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/*
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* Stream co - processor driver for the ETRAX FS
*
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* Copyright ( C ) 2003 - 2007 Axis Communications AB
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*/
# include <linux/init.h>
# include <linux/sched.h>
# include <linux/module.h>
# include <linux/slab.h>
# include <linux/string.h>
# include <linux/fs.h>
# include <linux/mm.h>
# include <linux/spinlock.h>
# include <linux/stddef.h>
# include <asm/uaccess.h>
# include <asm/io.h>
# include <asm/atomic.h>
# include <linux/list.h>
# include <linux/interrupt.h>
# include <asm/signal.h>
# include <asm/irq.h>
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# include <dma.h>
# include <hwregs/dma.h>
# include <hwregs/reg_map.h>
# include <hwregs/reg_rdwr.h>
# include <hwregs/intr_vect_defs.h>
# include <hwregs/strcop.h>
# include <hwregs/strcop_defs.h>
# include <cryptocop.h>
# ifdef CONFIG_ETRAXFS
# define IN_DMA 9
# define OUT_DMA 8
# define IN_DMA_INST regi_dma9
# define OUT_DMA_INST regi_dma8
# define DMA_IRQ DMA9_INTR_VECT
# else
# define IN_DMA 3
# define OUT_DMA 2
# define IN_DMA_INST regi_dma3
# define OUT_DMA_INST regi_dma2
# define DMA_IRQ DMA3_INTR_VECT
# endif
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# define DESCR_ALLOC_PAD (31)
struct cryptocop_dma_desc {
char * free_buf ; /* If non-null will be kfreed in free_cdesc() */
dma_descr_data * dma_descr ;
unsigned char dma_descr_buf [ sizeof ( dma_descr_data ) + DESCR_ALLOC_PAD ] ;
unsigned int from_pool : 1 ; /* If 1 'allocated' from the descriptor pool. */
struct cryptocop_dma_desc * next ;
} ;
struct cryptocop_int_operation {
void * alloc_ptr ;
cryptocop_session_id sid ;
dma_descr_context ctx_out ;
dma_descr_context ctx_in ;
/* DMA descriptors allocated by driver. */
struct cryptocop_dma_desc * cdesc_out ;
struct cryptocop_dma_desc * cdesc_in ;
/* Strcop config to use. */
cryptocop_3des_mode tdes_mode ;
cryptocop_csum_type csum_mode ;
/* DMA descrs provided by consumer. */
dma_descr_data * ddesc_out ;
dma_descr_data * ddesc_in ;
} ;
struct cryptocop_tfrm_ctx {
cryptocop_tfrm_id tid ;
unsigned int blocklength ;
unsigned int start_ix ;
struct cryptocop_tfrm_cfg * tcfg ;
struct cryptocop_transform_ctx * tctx ;
unsigned char previous_src ;
unsigned char current_src ;
/* Values to use in metadata out. */
unsigned char hash_conf ;
unsigned char hash_mode ;
unsigned char ciph_conf ;
unsigned char cbcmode ;
unsigned char decrypt ;
unsigned int requires_padding : 1 ;
unsigned int strict_block_length : 1 ;
unsigned int active : 1 ;
unsigned int done : 1 ;
size_t consumed ;
size_t produced ;
/* Pad (input) descriptors to put in the DMA out list when the transform
* output is put on the DMA in list . */
struct cryptocop_dma_desc * pad_descs ;
struct cryptocop_tfrm_ctx * prev_src ;
struct cryptocop_tfrm_ctx * curr_src ;
/* Mapping to HW. */
unsigned char unit_no ;
} ;
struct cryptocop_private {
cryptocop_session_id sid ;
struct cryptocop_private * next ;
} ;
/* Session list. */
struct cryptocop_transform_ctx {
struct cryptocop_transform_init init ;
unsigned char dec_key [ CRYPTOCOP_MAX_KEY_LENGTH ] ;
unsigned int dec_key_set : 1 ;
struct cryptocop_transform_ctx * next ;
} ;
struct cryptocop_session {
cryptocop_session_id sid ;
struct cryptocop_transform_ctx * tfrm_ctx ;
struct cryptocop_session * next ;
} ;
/* Priority levels for jobs sent to the cryptocop. Checksum operations from
kernel have highest priority since TCPIP stack processing must not
be a bottleneck . */
typedef enum {
cryptocop_prio_kernel_csum = 0 ,
cryptocop_prio_kernel = 1 ,
cryptocop_prio_user = 2 ,
cryptocop_prio_no_prios = 3
} cryptocop_queue_priority ;
struct cryptocop_prio_queue {
struct list_head jobs ;
cryptocop_queue_priority prio ;
} ;
struct cryptocop_prio_job {
struct list_head node ;
cryptocop_queue_priority prio ;
struct cryptocop_operation * oper ;
struct cryptocop_int_operation * iop ;
} ;
struct ioctl_job_cb_ctx {
unsigned int processed : 1 ;
} ;
static struct cryptocop_session * cryptocop_sessions = NULL ;
spinlock_t cryptocop_sessions_lock ;
/* Next Session ID to assign. */
static cryptocop_session_id next_sid = 1 ;
/* Pad for checksum. */
static const char csum_zero_pad [ 1 ] = { 0x00 } ;
/* Trash buffer for mem2mem operations. */
# define MEM2MEM_DISCARD_BUF_LENGTH (512)
static unsigned char mem2mem_discard_buf [ MEM2MEM_DISCARD_BUF_LENGTH ] ;
/* Descriptor pool. */
/* FIXME Tweak this value. */
# define CRYPTOCOP_DESCRIPTOR_POOL_SIZE (100)
static struct cryptocop_dma_desc descr_pool [ CRYPTOCOP_DESCRIPTOR_POOL_SIZE ] ;
static struct cryptocop_dma_desc * descr_pool_free_list ;
static int descr_pool_no_free ;
static spinlock_t descr_pool_lock ;
/* Lock to stop cryptocop to start processing of a new operation. The holder
of this lock MUST call cryptocop_start_job ( ) after it is unlocked . */
spinlock_t cryptocop_process_lock ;
static struct cryptocop_prio_queue cryptocop_job_queues [ cryptocop_prio_no_prios ] ;
static spinlock_t cryptocop_job_queue_lock ;
static struct cryptocop_prio_job * cryptocop_running_job = NULL ;
static spinlock_t running_job_lock ;
/* The interrupt handler appends completed jobs to this list. The scehduled
* tasklet removes them upon sending the response to the crypto consumer . */
static struct list_head cryptocop_completed_jobs ;
static spinlock_t cryptocop_completed_jobs_lock ;
DECLARE_WAIT_QUEUE_HEAD ( cryptocop_ioc_process_wq ) ;
/** Local functions. **/
static int cryptocop_open ( struct inode * , struct file * ) ;
static int cryptocop_release ( struct inode * , struct file * ) ;
static int cryptocop_ioctl ( struct inode * inode , struct file * file ,
unsigned int cmd , unsigned long arg ) ;
static void cryptocop_start_job ( void ) ;
static int cryptocop_job_queue_insert ( cryptocop_queue_priority prio , struct cryptocop_operation * operation ) ;
static int cryptocop_job_setup ( struct cryptocop_prio_job * * pj , struct cryptocop_operation * operation ) ;
static int cryptocop_job_queue_init ( void ) ;
static void cryptocop_job_queue_close ( void ) ;
static int create_md5_pad ( int alloc_flag , unsigned long long hashed_length , char * * pad , size_t * pad_length ) ;
static int create_sha1_pad ( int alloc_flag , unsigned long long hashed_length , char * * pad , size_t * pad_length ) ;
static int transform_ok ( struct cryptocop_transform_init * tinit ) ;
static struct cryptocop_session * get_session ( cryptocop_session_id sid ) ;
static struct cryptocop_transform_ctx * get_transform_ctx ( struct cryptocop_session * sess , cryptocop_tfrm_id tid ) ;
static void delete_internal_operation ( struct cryptocop_int_operation * iop ) ;
static void get_aes_decrypt_key ( unsigned char * dec_key , const unsigned char * key , unsigned int keylength ) ;
static int init_stream_coprocessor ( void ) ;
static void __exit exit_stream_coprocessor ( void ) ;
/*#define LDEBUG*/
# ifdef LDEBUG
# define DEBUG(s) s
# define DEBUG_API(s) s
static void print_cryptocop_operation ( struct cryptocop_operation * cop ) ;
static void print_dma_descriptors ( struct cryptocop_int_operation * iop ) ;
static void print_strcop_crypto_op ( struct strcop_crypto_op * cop ) ;
static void print_lock_status ( void ) ;
static void print_user_dma_lists ( struct cryptocop_dma_list_operation * dma_op ) ;
# define assert(s) do{if (!(s)) panic(#s);} while(0);
# else
# define DEBUG(s)
# define DEBUG_API(s)
# define assert(s)
# endif
/* Transform constants. */
# define DES_BLOCK_LENGTH (8)
# define AES_BLOCK_LENGTH (16)
# define MD5_BLOCK_LENGTH (64)
# define SHA1_BLOCK_LENGTH (64)
# define CSUM_BLOCK_LENGTH (2)
# define MD5_STATE_LENGTH (16)
# define SHA1_STATE_LENGTH (20)
/* The device number. */
# define CRYPTOCOP_MAJOR (254)
# define CRYPTOCOP_MINOR (0)
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const struct file_operations cryptocop_fops = {
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. owner = THIS_MODULE ,
. open = cryptocop_open ,
. release = cryptocop_release ,
. ioctl = cryptocop_ioctl
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} ;
static void free_cdesc ( struct cryptocop_dma_desc * cdesc )
{
DEBUG ( printk ( " free_cdesc: cdesc 0x%p, from_pool=%d \n " , cdesc , cdesc - > from_pool ) ) ;
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kfree ( cdesc - > free_buf ) ;
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if ( cdesc - > from_pool ) {
unsigned long int flags ;
spin_lock_irqsave ( & descr_pool_lock , flags ) ;
cdesc - > next = descr_pool_free_list ;
descr_pool_free_list = cdesc ;
+ + descr_pool_no_free ;
spin_unlock_irqrestore ( & descr_pool_lock , flags ) ;
} else {
kfree ( cdesc ) ;
}
}
static struct cryptocop_dma_desc * alloc_cdesc ( int alloc_flag )
{
int use_pool = ( alloc_flag & GFP_ATOMIC ) ? 1 : 0 ;
struct cryptocop_dma_desc * cdesc ;
if ( use_pool ) {
unsigned long int flags ;
spin_lock_irqsave ( & descr_pool_lock , flags ) ;
if ( ! descr_pool_free_list ) {
spin_unlock_irqrestore ( & descr_pool_lock , flags ) ;
DEBUG_API ( printk ( " alloc_cdesc: pool is empty \n " ) ) ;
return NULL ;
}
cdesc = descr_pool_free_list ;
descr_pool_free_list = descr_pool_free_list - > next ;
- - descr_pool_no_free ;
spin_unlock_irqrestore ( & descr_pool_lock , flags ) ;
cdesc - > from_pool = 1 ;
} else {
cdesc = kmalloc ( sizeof ( struct cryptocop_dma_desc ) , alloc_flag ) ;
if ( ! cdesc ) {
DEBUG_API ( printk ( " alloc_cdesc: kmalloc \n " ) ) ;
return NULL ;
}
cdesc - > from_pool = 0 ;
}
cdesc - > dma_descr = ( dma_descr_data * ) ( ( ( unsigned long int ) cdesc + offsetof ( struct cryptocop_dma_desc , dma_descr_buf ) + DESCR_ALLOC_PAD ) & ~ 0x0000001F ) ;
cdesc - > next = NULL ;
cdesc - > free_buf = NULL ;
cdesc - > dma_descr - > out_eop = 0 ;
cdesc - > dma_descr - > in_eop = 0 ;
cdesc - > dma_descr - > intr = 0 ;
cdesc - > dma_descr - > eol = 0 ;
cdesc - > dma_descr - > wait = 0 ;
cdesc - > dma_descr - > buf = NULL ;
cdesc - > dma_descr - > after = NULL ;
DEBUG_API ( printk ( " alloc_cdesc: return 0x%p, cdesc->dma_descr=0x%p, from_pool=%d \n " , cdesc , cdesc - > dma_descr , cdesc - > from_pool ) ) ;
return cdesc ;
}
static void setup_descr_chain ( struct cryptocop_dma_desc * cd )
{
DEBUG ( printk ( " setup_descr_chain: entering \n " ) ) ;
while ( cd ) {
if ( cd - > next ) {
cd - > dma_descr - > next = ( dma_descr_data * ) virt_to_phys ( cd - > next - > dma_descr ) ;
} else {
cd - > dma_descr - > next = NULL ;
}
cd = cd - > next ;
}
DEBUG ( printk ( " setup_descr_chain: exit \n " ) ) ;
}
/* Create a pad descriptor for the transform.
* Return - 1 for error , 0 if pad created . */
static int create_pad_descriptor ( struct cryptocop_tfrm_ctx * tc , struct cryptocop_dma_desc * * pad_desc , int alloc_flag )
{
struct cryptocop_dma_desc * cdesc = NULL ;
int error = 0 ;
struct strcop_meta_out mo = {
. ciphsel = src_none ,
. hashsel = src_none ,
. csumsel = src_none
} ;
char * pad ;
size_t plen ;
DEBUG ( printk ( " create_pad_descriptor: start. \n " ) ) ;
/* Setup pad descriptor. */
DEBUG ( printk ( " create_pad_descriptor: setting up padding. \n " ) ) ;
cdesc = alloc_cdesc ( alloc_flag ) ;
if ( ! cdesc ) {
DEBUG_API ( printk ( " create_pad_descriptor: alloc pad desc \n " ) ) ;
goto error_cleanup ;
}
switch ( tc - > unit_no ) {
case src_md5 :
error = create_md5_pad ( alloc_flag , tc - > consumed , & pad , & plen ) ;
if ( error ) {
DEBUG_API ( printk ( " create_pad_descriptor: create_md5_pad_failed \n " ) ) ;
goto error_cleanup ;
}
cdesc - > free_buf = pad ;
mo . hashsel = src_dma ;
mo . hashconf = tc - > hash_conf ;
mo . hashmode = tc - > hash_mode ;
break ;
case src_sha1 :
error = create_sha1_pad ( alloc_flag , tc - > consumed , & pad , & plen ) ;
if ( error ) {
DEBUG_API ( printk ( " create_pad_descriptor: create_sha1_pad_failed \n " ) ) ;
goto error_cleanup ;
}
cdesc - > free_buf = pad ;
mo . hashsel = src_dma ;
mo . hashconf = tc - > hash_conf ;
mo . hashmode = tc - > hash_mode ;
break ;
case src_csum :
if ( tc - > consumed % tc - > blocklength ) {
pad = ( char * ) csum_zero_pad ;
plen = 1 ;
} else {
pad = ( char * ) cdesc ; /* Use any pointer. */
plen = 0 ;
}
mo . csumsel = src_dma ;
break ;
}
cdesc - > dma_descr - > wait = 1 ;
cdesc - > dma_descr - > out_eop = 1 ; /* Since this is a pad output is pushed. EOP is ok here since the padded unit is the only one active. */
cdesc - > dma_descr - > buf = ( char * ) virt_to_phys ( ( char * ) pad ) ;
cdesc - > dma_descr - > after = cdesc - > dma_descr - > buf + plen ;
cdesc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_out , mo ) ;
* pad_desc = cdesc ;
return 0 ;
error_cleanup :
if ( cdesc ) free_cdesc ( cdesc ) ;
return - 1 ;
}
static int setup_key_dl_desc ( struct cryptocop_tfrm_ctx * tc , struct cryptocop_dma_desc * * kd , int alloc_flag )
{
struct cryptocop_dma_desc * key_desc = alloc_cdesc ( alloc_flag ) ;
struct strcop_meta_out mo = { 0 } ;
DEBUG ( printk ( " setup_key_dl_desc \n " ) ) ;
if ( ! key_desc ) {
DEBUG_API ( printk ( " setup_key_dl_desc: failed descriptor allocation. \n " ) ) ;
return - ENOMEM ;
}
/* Download key. */
if ( ( tc - > tctx - > init . alg = = cryptocop_alg_aes ) & & ( tc - > tcfg - > flags & CRYPTOCOP_DECRYPT ) ) {
/* Precook the AES decrypt key. */
if ( ! tc - > tctx - > dec_key_set ) {
get_aes_decrypt_key ( tc - > tctx - > dec_key , tc - > tctx - > init . key , tc - > tctx - > init . keylen ) ;
tc - > tctx - > dec_key_set = 1 ;
}
key_desc - > dma_descr - > buf = ( char * ) virt_to_phys ( tc - > tctx - > dec_key ) ;
key_desc - > dma_descr - > after = key_desc - > dma_descr - > buf + tc - > tctx - > init . keylen / 8 ;
} else {
key_desc - > dma_descr - > buf = ( char * ) virt_to_phys ( tc - > tctx - > init . key ) ;
key_desc - > dma_descr - > after = key_desc - > dma_descr - > buf + tc - > tctx - > init . keylen / 8 ;
}
/* Setup metadata. */
mo . dlkey = 1 ;
switch ( tc - > tctx - > init . keylen ) {
case 64 :
mo . decrypt = 0 ;
mo . hashmode = 0 ;
break ;
case 128 :
mo . decrypt = 0 ;
mo . hashmode = 1 ;
break ;
case 192 :
mo . decrypt = 1 ;
mo . hashmode = 0 ;
break ;
case 256 :
mo . decrypt = 1 ;
mo . hashmode = 1 ;
break ;
default :
break ;
}
mo . ciphsel = mo . hashsel = mo . csumsel = src_none ;
key_desc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_out , mo ) ;
key_desc - > dma_descr - > out_eop = 1 ;
key_desc - > dma_descr - > wait = 1 ;
key_desc - > dma_descr - > intr = 0 ;
* kd = key_desc ;
return 0 ;
}
static int setup_cipher_iv_desc ( struct cryptocop_tfrm_ctx * tc , struct cryptocop_dma_desc * * id , int alloc_flag )
{
struct cryptocop_dma_desc * iv_desc = alloc_cdesc ( alloc_flag ) ;
struct strcop_meta_out mo = { 0 } ;
DEBUG ( printk ( " setup_cipher_iv_desc \n " ) ) ;
if ( ! iv_desc ) {
DEBUG_API ( printk ( " setup_cipher_iv_desc: failed CBC IV descriptor allocation. \n " ) ) ;
return - ENOMEM ;
}
/* Download IV. */
iv_desc - > dma_descr - > buf = ( char * ) virt_to_phys ( tc - > tcfg - > iv ) ;
iv_desc - > dma_descr - > after = iv_desc - > dma_descr - > buf + tc - > blocklength ;
/* Setup metadata. */
mo . hashsel = mo . csumsel = src_none ;
mo . ciphsel = src_dma ;
mo . ciphconf = tc - > ciph_conf ;
mo . cbcmode = tc - > cbcmode ;
iv_desc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_out , mo ) ;
iv_desc - > dma_descr - > out_eop = 0 ;
iv_desc - > dma_descr - > wait = 1 ;
iv_desc - > dma_descr - > intr = 0 ;
* id = iv_desc ;
return 0 ;
}
/* Map the ouput length of the transform to operation output starting on the inject index. */
static int create_input_descriptors ( struct cryptocop_operation * operation , struct cryptocop_tfrm_ctx * tc , struct cryptocop_dma_desc * * id , int alloc_flag )
{
int err = 0 ;
struct cryptocop_dma_desc head = { 0 } ;
struct cryptocop_dma_desc * outdesc = & head ;
size_t iov_offset = 0 ;
size_t out_ix = 0 ;
int outiov_ix = 0 ;
struct strcop_meta_in mi = { 0 } ;
size_t out_length = tc - > produced ;
int rem_length ;
int dlength ;
assert ( out_length ! = 0 ) ;
if ( ( ( tc - > produced + tc - > tcfg - > inject_ix ) > operation - > tfrm_op . outlen ) | | ( tc - > produced & & ( operation - > tfrm_op . outlen = = 0 ) ) ) {
DEBUG_API ( printk ( " create_input_descriptors: operation outdata too small \n " ) ) ;
return - EINVAL ;
}
/* Traverse the out iovec until the result inject index is reached. */
while ( ( outiov_ix < operation - > tfrm_op . outcount ) & & ( ( out_ix + operation - > tfrm_op . outdata [ outiov_ix ] . iov_len ) < = tc - > tcfg - > inject_ix ) ) {
out_ix + = operation - > tfrm_op . outdata [ outiov_ix ] . iov_len ;
outiov_ix + + ;
}
if ( outiov_ix > = operation - > tfrm_op . outcount ) {
DEBUG_API ( printk ( " create_input_descriptors: operation outdata too small \n " ) ) ;
return - EINVAL ;
}
iov_offset = tc - > tcfg - > inject_ix - out_ix ;
mi . dmasel = tc - > unit_no ;
/* Setup the output descriptors. */
while ( ( out_length > 0 ) & & ( outiov_ix < operation - > tfrm_op . outcount ) ) {
outdesc - > next = alloc_cdesc ( alloc_flag ) ;
if ( ! outdesc - > next ) {
DEBUG_API ( printk ( " create_input_descriptors: alloc_cdesc \n " ) ) ;
err = - ENOMEM ;
goto error_cleanup ;
}
outdesc = outdesc - > next ;
rem_length = operation - > tfrm_op . outdata [ outiov_ix ] . iov_len - iov_offset ;
dlength = ( out_length < rem_length ) ? out_length : rem_length ;
DEBUG ( printk ( " create_input_descriptors: \n "
" outiov_ix=%d, rem_length=%d, dlength=%d \n "
" iov_offset=%d, outdata[outiov_ix].iov_len=%d \n "
" outcount=%d, outiov_ix=%d \n " ,
outiov_ix , rem_length , dlength , iov_offset , operation - > tfrm_op . outdata [ outiov_ix ] . iov_len , operation - > tfrm_op . outcount , outiov_ix ) ) ;
outdesc - > dma_descr - > buf = ( char * ) virt_to_phys ( operation - > tfrm_op . outdata [ outiov_ix ] . iov_base + iov_offset ) ;
outdesc - > dma_descr - > after = outdesc - > dma_descr - > buf + dlength ;
outdesc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_in , mi ) ;
out_length - = dlength ;
iov_offset + = dlength ;
if ( iov_offset > = operation - > tfrm_op . outdata [ outiov_ix ] . iov_len ) {
iov_offset = 0 ;
+ + outiov_ix ;
}
}
if ( out_length > 0 ) {
DEBUG_API ( printk ( " create_input_descriptors: not enough room for output, %d remained \n " , out_length ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
/* Set sync in last descriptor. */
mi . sync = 1 ;
outdesc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_in , mi ) ;
* id = head . next ;
return 0 ;
error_cleanup :
while ( head . next ) {
outdesc = head . next - > next ;
free_cdesc ( head . next ) ;
head . next = outdesc ;
}
return err ;
}
static int create_output_descriptors ( struct cryptocop_operation * operation , int * iniov_ix , int * iniov_offset , size_t desc_len , struct cryptocop_dma_desc * * current_out_cdesc , struct strcop_meta_out * meta_out , int alloc_flag )
{
while ( desc_len ! = 0 ) {
struct cryptocop_dma_desc * cdesc ;
int rem_length = operation - > tfrm_op . indata [ * iniov_ix ] . iov_len - * iniov_offset ;
int dlength = ( desc_len < rem_length ) ? desc_len : rem_length ;
cdesc = alloc_cdesc ( alloc_flag ) ;
if ( ! cdesc ) {
DEBUG_API ( printk ( " create_output_descriptors: alloc_cdesc \n " ) ) ;
return - ENOMEM ;
}
( * current_out_cdesc ) - > next = cdesc ;
( * current_out_cdesc ) = cdesc ;
cdesc - > free_buf = NULL ;
cdesc - > dma_descr - > buf = ( char * ) virt_to_phys ( operation - > tfrm_op . indata [ * iniov_ix ] . iov_base + * iniov_offset ) ;
cdesc - > dma_descr - > after = cdesc - > dma_descr - > buf + dlength ;
desc_len - = dlength ;
* iniov_offset + = dlength ;
assert ( desc_len > = 0 ) ;
if ( * iniov_offset > = operation - > tfrm_op . indata [ * iniov_ix ] . iov_len ) {
* iniov_offset = 0 ;
+ + ( * iniov_ix ) ;
if ( * iniov_ix > operation - > tfrm_op . incount ) {
DEBUG_API ( printk ( " create_output_descriptors: not enough indata in operation. " ) ) ;
return - EINVAL ;
}
}
cdesc - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_out , ( * meta_out ) ) ;
} /* while (desc_len != 0) */
/* Last DMA descriptor gets a 'wait' bit to signal expected change in metadata. */
( * current_out_cdesc ) - > dma_descr - > wait = 1 ; /* This will set extraneous WAIT in some situations, e.g. when padding hashes and checksums. */
return 0 ;
}
static int append_input_descriptors ( struct cryptocop_operation * operation , struct cryptocop_dma_desc * * current_in_cdesc , struct cryptocop_dma_desc * * current_out_cdesc , struct cryptocop_tfrm_ctx * tc , int alloc_flag )
{
DEBUG ( printk ( " append_input_descriptors, tc=0x%p, unit_no=%d \n " , tc , tc - > unit_no ) ) ;
if ( tc - > tcfg ) {
int failed = 0 ;
struct cryptocop_dma_desc * idescs = NULL ;
DEBUG ( printk ( " append_input_descriptors: pushing output, consumed %d produced %d bytes. \n " , tc - > consumed , tc - > produced ) ) ;
if ( tc - > pad_descs ) {
DEBUG ( printk ( " append_input_descriptors: append pad descriptors to DMA out list. \n " ) ) ;
while ( tc - > pad_descs ) {
DEBUG ( printk ( " append descriptor 0x%p \n " , tc - > pad_descs ) ) ;
( * current_out_cdesc ) - > next = tc - > pad_descs ;
tc - > pad_descs = tc - > pad_descs - > next ;
( * current_out_cdesc ) = ( * current_out_cdesc ) - > next ;
}
}
/* Setup and append output descriptors to DMA in list. */
if ( tc - > unit_no = = src_dma ) {
/* mem2mem. Setup DMA in descriptors to discard all input prior to the requested mem2mem data. */
struct strcop_meta_in mi = { . sync = 0 , . dmasel = src_dma } ;
unsigned int start_ix = tc - > start_ix ;
while ( start_ix ) {
unsigned int desclen = start_ix < MEM2MEM_DISCARD_BUF_LENGTH ? start_ix : MEM2MEM_DISCARD_BUF_LENGTH ;
( * current_in_cdesc ) - > next = alloc_cdesc ( alloc_flag ) ;
if ( ! ( * current_in_cdesc ) - > next ) {
DEBUG_API ( printk ( " append_input_descriptors: alloc_cdesc mem2mem discard failed \n " ) ) ;
return - ENOMEM ;
}
( * current_in_cdesc ) = ( * current_in_cdesc ) - > next ;
( * current_in_cdesc ) - > dma_descr - > buf = ( char * ) virt_to_phys ( mem2mem_discard_buf ) ;
( * current_in_cdesc ) - > dma_descr - > after = ( * current_in_cdesc ) - > dma_descr - > buf + desclen ;
( * current_in_cdesc ) - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_in , mi ) ;
start_ix - = desclen ;
}
mi . sync = 1 ;
( * current_in_cdesc ) - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_in , mi ) ;
}
failed = create_input_descriptors ( operation , tc , & idescs , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " append_input_descriptors: output descriptor setup failed \n " ) ) ;
return failed ;
}
DEBUG ( printk ( " append_input_descriptors: append output descriptors to DMA in list. \n " ) ) ;
while ( idescs ) {
DEBUG ( printk ( " append descriptor 0x%p \n " , idescs ) ) ;
( * current_in_cdesc ) - > next = idescs ;
idescs = idescs - > next ;
( * current_in_cdesc ) = ( * current_in_cdesc ) - > next ;
}
}
return 0 ;
}
static int cryptocop_setup_dma_list ( struct cryptocop_operation * operation , struct cryptocop_int_operation * * int_op , int alloc_flag )
{
struct cryptocop_session * sess ;
struct cryptocop_transform_ctx * tctx ;
struct cryptocop_tfrm_ctx digest_ctx = {
. previous_src = src_none ,
. current_src = src_none ,
. start_ix = 0 ,
. requires_padding = 1 ,
. strict_block_length = 0 ,
. hash_conf = 0 ,
. hash_mode = 0 ,
. ciph_conf = 0 ,
. cbcmode = 0 ,
. decrypt = 0 ,
. consumed = 0 ,
. produced = 0 ,
. pad_descs = NULL ,
. active = 0 ,
. done = 0 ,
. prev_src = NULL ,
. curr_src = NULL ,
. tcfg = NULL } ;
struct cryptocop_tfrm_ctx cipher_ctx = {
. previous_src = src_none ,
. current_src = src_none ,
. start_ix = 0 ,
. requires_padding = 0 ,
. strict_block_length = 1 ,
. hash_conf = 0 ,
. hash_mode = 0 ,
. ciph_conf = 0 ,
. cbcmode = 0 ,
. decrypt = 0 ,
. consumed = 0 ,
. produced = 0 ,
. pad_descs = NULL ,
. active = 0 ,
. done = 0 ,
. prev_src = NULL ,
. curr_src = NULL ,
. tcfg = NULL } ;
struct cryptocop_tfrm_ctx csum_ctx = {
. previous_src = src_none ,
. current_src = src_none ,
. start_ix = 0 ,
. blocklength = 2 ,
. requires_padding = 1 ,
. strict_block_length = 0 ,
. hash_conf = 0 ,
. hash_mode = 0 ,
. ciph_conf = 0 ,
. cbcmode = 0 ,
. decrypt = 0 ,
. consumed = 0 ,
. produced = 0 ,
. pad_descs = NULL ,
. active = 0 ,
. done = 0 ,
. tcfg = NULL ,
. prev_src = NULL ,
. curr_src = NULL ,
. unit_no = src_csum } ;
struct cryptocop_tfrm_cfg * tcfg = operation - > tfrm_op . tfrm_cfg ;
unsigned int indata_ix = 0 ;
/* iovec accounting. */
int iniov_ix = 0 ;
int iniov_offset = 0 ;
/* Operation descriptor cfg traversal pointer. */
struct cryptocop_desc * odsc ;
int failed = 0 ;
/* List heads for allocated descriptors. */
struct cryptocop_dma_desc out_cdesc_head = { 0 } ;
struct cryptocop_dma_desc in_cdesc_head = { 0 } ;
struct cryptocop_dma_desc * current_out_cdesc = & out_cdesc_head ;
struct cryptocop_dma_desc * current_in_cdesc = & in_cdesc_head ;
struct cryptocop_tfrm_ctx * output_tc = NULL ;
void * iop_alloc_ptr ;
assert ( operation ! = NULL ) ;
assert ( int_op ! = NULL ) ;
DEBUG ( printk ( " cryptocop_setup_dma_list: start \n " ) ) ;
DEBUG ( print_cryptocop_operation ( operation ) ) ;
sess = get_session ( operation - > sid ) ;
if ( ! sess ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: no session found for operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
iop_alloc_ptr = kmalloc ( DESCR_ALLOC_PAD + sizeof ( struct cryptocop_int_operation ) , alloc_flag ) ;
if ( ! iop_alloc_ptr ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: kmalloc cryptocop_int_operation \n " ) ) ;
failed = - ENOMEM ;
goto error_cleanup ;
}
( * int_op ) = ( struct cryptocop_int_operation * ) ( ( ( unsigned long int ) ( iop_alloc_ptr + DESCR_ALLOC_PAD + offsetof ( struct cryptocop_int_operation , ctx_out ) ) & ~ 0x0000001F ) - offsetof ( struct cryptocop_int_operation , ctx_out ) ) ;
DEBUG ( memset ( ( * int_op ) , 0xff , sizeof ( struct cryptocop_int_operation ) ) ) ;
( * int_op ) - > alloc_ptr = iop_alloc_ptr ;
DEBUG ( printk ( " cryptocop_setup_dma_list: *int_op=0x%p, alloc_ptr=0x%p \n " , * int_op , ( * int_op ) - > alloc_ptr ) ) ;
( * int_op ) - > sid = operation - > sid ;
( * int_op ) - > cdesc_out = NULL ;
( * int_op ) - > cdesc_in = NULL ;
( * int_op ) - > tdes_mode = cryptocop_3des_ede ;
( * int_op ) - > csum_mode = cryptocop_csum_le ;
( * int_op ) - > ddesc_out = NULL ;
( * int_op ) - > ddesc_in = NULL ;
/* Scan operation->tfrm_op.tfrm_cfg for bad configuration and set up the local contexts. */
if ( ! tcfg ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: no configured transforms in operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
while ( tcfg ) {
tctx = get_transform_ctx ( sess , tcfg - > tid ) ;
if ( ! tctx ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: no transform id %d in session. \n " , tcfg - > tid ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( tcfg - > inject_ix > operation - > tfrm_op . outlen ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: transform id %d inject_ix (%d) > operation->tfrm_op.outlen(%d) " , tcfg - > tid , tcfg - > inject_ix , operation - > tfrm_op . outlen ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
switch ( tctx - > init . alg ) {
case cryptocop_alg_mem2mem :
if ( cipher_ctx . tcfg ! = NULL ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: multiple ciphers in operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
/* mem2mem is handled as a NULL cipher. */
cipher_ctx . cbcmode = 0 ;
cipher_ctx . decrypt = 0 ;
cipher_ctx . blocklength = 1 ;
cipher_ctx . ciph_conf = 0 ;
cipher_ctx . unit_no = src_dma ;
cipher_ctx . tcfg = tcfg ;
cipher_ctx . tctx = tctx ;
break ;
case cryptocop_alg_des :
case cryptocop_alg_3des :
case cryptocop_alg_aes :
/* cipher */
if ( cipher_ctx . tcfg ! = NULL ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: multiple ciphers in operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
cipher_ctx . tcfg = tcfg ;
cipher_ctx . tctx = tctx ;
if ( cipher_ctx . tcfg - > flags & CRYPTOCOP_DECRYPT ) {
cipher_ctx . decrypt = 1 ;
}
switch ( tctx - > init . cipher_mode ) {
case cryptocop_cipher_mode_ecb :
cipher_ctx . cbcmode = 0 ;
break ;
case cryptocop_cipher_mode_cbc :
cipher_ctx . cbcmode = 1 ;
break ;
default :
DEBUG_API ( printk ( " cryptocop_setup_dma_list: cipher_ctx, bad cipher mode==%d \n " , tctx - > init . cipher_mode ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
DEBUG ( printk ( " cryptocop_setup_dma_list: cipher_ctx, set CBC mode==%d \n " , cipher_ctx . cbcmode ) ) ;
switch ( tctx - > init . alg ) {
case cryptocop_alg_des :
cipher_ctx . ciph_conf = 0 ;
cipher_ctx . unit_no = src_des ;
cipher_ctx . blocklength = DES_BLOCK_LENGTH ;
break ;
case cryptocop_alg_3des :
cipher_ctx . ciph_conf = 1 ;
cipher_ctx . unit_no = src_des ;
cipher_ctx . blocklength = DES_BLOCK_LENGTH ;
break ;
case cryptocop_alg_aes :
cipher_ctx . ciph_conf = 2 ;
cipher_ctx . unit_no = src_aes ;
cipher_ctx . blocklength = AES_BLOCK_LENGTH ;
break ;
default :
panic ( " cryptocop_setup_dma_list: impossible algorithm %d \n " , tctx - > init . alg ) ;
}
( * int_op ) - > tdes_mode = tctx - > init . tdes_mode ;
break ;
case cryptocop_alg_md5 :
case cryptocop_alg_sha1 :
/* digest */
if ( digest_ctx . tcfg ! = NULL ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: multiple digests in operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
digest_ctx . tcfg = tcfg ;
digest_ctx . tctx = tctx ;
digest_ctx . hash_mode = 0 ; /* Don't use explicit IV in this API. */
switch ( tctx - > init . alg ) {
case cryptocop_alg_md5 :
digest_ctx . blocklength = MD5_BLOCK_LENGTH ;
digest_ctx . unit_no = src_md5 ;
digest_ctx . hash_conf = 1 ; /* 1 => MD-5 */
break ;
case cryptocop_alg_sha1 :
digest_ctx . blocklength = SHA1_BLOCK_LENGTH ;
digest_ctx . unit_no = src_sha1 ;
digest_ctx . hash_conf = 0 ; /* 0 => SHA-1 */
break ;
default :
panic ( " cryptocop_setup_dma_list: impossible digest algorithm \n " ) ;
}
break ;
case cryptocop_alg_csum :
/* digest */
if ( csum_ctx . tcfg ! = NULL ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: multiple checksums in operation. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
( * int_op ) - > csum_mode = tctx - > init . csum_mode ;
csum_ctx . tcfg = tcfg ;
csum_ctx . tctx = tctx ;
break ;
default :
/* no algorithm. */
DEBUG_API ( printk ( " cryptocop_setup_dma_list: invalid algorithm %d specified in tfrm %d. \n " , tctx - > init . alg , tcfg - > tid ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
tcfg = tcfg - > next ;
}
/* Download key if a cipher is used. */
if ( cipher_ctx . tcfg & & ( cipher_ctx . tctx - > init . alg ! = cryptocop_alg_mem2mem ) ) {
struct cryptocop_dma_desc * key_desc = NULL ;
failed = setup_key_dl_desc ( & cipher_ctx , & key_desc , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: setup key dl \n " ) ) ;
goto error_cleanup ;
}
current_out_cdesc - > next = key_desc ;
current_out_cdesc = key_desc ;
indata_ix + = ( unsigned int ) ( key_desc - > dma_descr - > after - key_desc - > dma_descr - > buf ) ;
/* Download explicit IV if a cipher is used and CBC mode and explicit IV selected. */
if ( ( cipher_ctx . tctx - > init . cipher_mode = = cryptocop_cipher_mode_cbc ) & & ( cipher_ctx . tcfg - > flags & CRYPTOCOP_EXPLICIT_IV ) ) {
struct cryptocop_dma_desc * iv_desc = NULL ;
DEBUG ( printk ( " cryptocop_setup_dma_list: setup cipher CBC IV descriptor. \n " ) ) ;
failed = setup_cipher_iv_desc ( & cipher_ctx , & iv_desc , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: CBC IV descriptor. \n " ) ) ;
goto error_cleanup ;
}
current_out_cdesc - > next = iv_desc ;
current_out_cdesc = iv_desc ;
indata_ix + = ( unsigned int ) ( iv_desc - > dma_descr - > after - iv_desc - > dma_descr - > buf ) ;
}
}
/* Process descriptors. */
odsc = operation - > tfrm_op . desc ;
while ( odsc ) {
struct cryptocop_desc_cfg * dcfg = odsc - > cfg ;
struct strcop_meta_out meta_out = { 0 } ;
size_t desc_len = odsc - > length ;
int active_count , eop_needed_count ;
output_tc = NULL ;
DEBUG ( printk ( " cryptocop_setup_dma_list: parsing an operation descriptor \n " ) ) ;
while ( dcfg ) {
struct cryptocop_tfrm_ctx * tc = NULL ;
DEBUG ( printk ( " cryptocop_setup_dma_list: parsing an operation descriptor configuration. \n " ) ) ;
/* Get the local context for the transform and mark it as the output unit if it produces output. */
if ( digest_ctx . tcfg & & ( digest_ctx . tcfg - > tid = = dcfg - > tid ) ) {
tc = & digest_ctx ;
} else if ( cipher_ctx . tcfg & & ( cipher_ctx . tcfg - > tid = = dcfg - > tid ) ) {
tc = & cipher_ctx ;
} else if ( csum_ctx . tcfg & & ( csum_ctx . tcfg - > tid = = dcfg - > tid ) ) {
tc = & csum_ctx ;
}
if ( ! tc ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: invalid transform %d specified in descriptor. \n " , dcfg - > tid ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( tc - > done ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: completed transform %d reused. \n " , dcfg - > tid ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( ! tc - > active ) {
tc - > start_ix = indata_ix ;
tc - > active = 1 ;
}
tc - > previous_src = tc - > current_src ;
tc - > prev_src = tc - > curr_src ;
/* Map source unit id to DMA source config. */
switch ( dcfg - > src ) {
case cryptocop_source_dma :
tc - > current_src = src_dma ;
break ;
case cryptocop_source_des :
tc - > current_src = src_des ;
break ;
case cryptocop_source_3des :
tc - > current_src = src_des ;
break ;
case cryptocop_source_aes :
tc - > current_src = src_aes ;
break ;
case cryptocop_source_md5 :
case cryptocop_source_sha1 :
case cryptocop_source_csum :
case cryptocop_source_none :
default :
/* We do not allow using accumulating style units (SHA-1, MD5, checksum) as sources to other units.
*/
DEBUG_API ( printk ( " cryptocop_setup_dma_list: bad unit source configured %d. \n " , dcfg - > src ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( tc - > current_src ! = src_dma ) {
/* Find the unit we are sourcing from. */
if ( digest_ctx . unit_no = = tc - > current_src ) {
tc - > curr_src = & digest_ctx ;
} else if ( cipher_ctx . unit_no = = tc - > current_src ) {
tc - > curr_src = & cipher_ctx ;
} else if ( csum_ctx . unit_no = = tc - > current_src ) {
tc - > curr_src = & csum_ctx ;
}
if ( ( tc - > curr_src = = tc ) & & ( tc - > unit_no ! = src_dma ) ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: unit %d configured to source from itself. \n " , tc - > unit_no ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
} else {
tc - > curr_src = NULL ;
}
/* Detect source switch. */
DEBUG ( printk ( " cryptocop_setup_dma_list: tc->active=%d tc->unit_no=%d tc->current_src=%d tc->previous_src=%d, tc->curr_src=0x%p, tc->prev_srv=0x%p \n " , tc - > active , tc - > unit_no , tc - > current_src , tc - > previous_src , tc - > curr_src , tc - > prev_src ) ) ;
if ( tc - > active & & ( tc - > current_src ! = tc - > previous_src ) ) {
/* Only allow source switch when both the old source unit and the new one have
* no pending data to process ( i . e . the consumed length must be a multiple of the
* transform blocklength ) . */
/* Note: if the src == NULL we are actually sourcing from DMA out. */
if ( ( ( tc - > prev_src ! = NULL ) & & ( tc - > prev_src - > consumed % tc - > prev_src - > blocklength ) ) | |
( ( tc - > curr_src ! = NULL ) & & ( tc - > curr_src - > consumed % tc - > curr_src - > blocklength ) ) )
{
DEBUG_API ( printk ( " cryptocop_setup_dma_list: can only disconnect from or connect to a unit on a multiple of the blocklength, old: cons=%d, prod=%d, block=%d, new: cons=%d prod=%d, block=%d. \n " , tc - > prev_src ? tc - > prev_src - > consumed : INT_MIN , tc - > prev_src ? tc - > prev_src - > produced : INT_MIN , tc - > prev_src ? tc - > prev_src - > blocklength : INT_MIN , tc - > curr_src ? tc - > curr_src - > consumed : INT_MIN , tc - > curr_src ? tc - > curr_src - > produced : INT_MIN , tc - > curr_src ? tc - > curr_src - > blocklength : INT_MIN ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
}
/* Detect unit deactivation. */
if ( dcfg - > last ) {
/* Length check of this is handled below. */
tc - > done = 1 ;
}
dcfg = dcfg - > next ;
} /* while (dcfg) */
DEBUG ( printk ( " cryptocop_setup_dma_list: parsing operation descriptor configuration complete. \n " ) ) ;
if ( cipher_ctx . active & & ( cipher_ctx . curr_src ! = NULL ) & & ! cipher_ctx . curr_src - > active ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: cipher source from inactive unit %d \n " , cipher_ctx . curr_src - > unit_no ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( digest_ctx . active & & ( digest_ctx . curr_src ! = NULL ) & & ! digest_ctx . curr_src - > active ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: digest source from inactive unit %d \n " , digest_ctx . curr_src - > unit_no ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( csum_ctx . active & & ( csum_ctx . curr_src ! = NULL ) & & ! csum_ctx . curr_src - > active ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: cipher source from inactive unit %d \n " , csum_ctx . curr_src - > unit_no ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
/* Update consumed and produced lengths.
The consumed length accounting here is actually cheating . If a unit source from DMA ( or any
other unit that process data in blocks of one octet ) it is correct , but if it source from a
block processing unit , i . e . a cipher , it will be temporarily incorrect at some times . However
since it is only allowed - - by the HW - - to change source to or from a block processing unit at times where that
unit has processed an exact multiple of its block length the end result will be correct .
Beware that if the source change restriction change this code will need to be ( much ) reworked .
*/
DEBUG ( printk ( " cryptocop_setup_dma_list: desc->length=%d, desc_len=%d. \n " , odsc - > length , desc_len ) ) ;
if ( csum_ctx . active ) {
csum_ctx . consumed + = desc_len ;
if ( csum_ctx . done ) {
csum_ctx . produced = 2 ;
}
DEBUG ( printk ( " cryptocop_setup_dma_list: csum_ctx producing: consumed=%d, produced=%d, blocklength=%d. \n " , csum_ctx . consumed , csum_ctx . produced , csum_ctx . blocklength ) ) ;
}
if ( digest_ctx . active ) {
digest_ctx . consumed + = desc_len ;
if ( digest_ctx . done ) {
if ( digest_ctx . unit_no = = src_md5 ) {
digest_ctx . produced = MD5_STATE_LENGTH ;
} else {
digest_ctx . produced = SHA1_STATE_LENGTH ;
}
}
DEBUG ( printk ( " cryptocop_setup_dma_list: digest_ctx producing: consumed=%d, produced=%d, blocklength=%d. \n " , digest_ctx . consumed , digest_ctx . produced , digest_ctx . blocklength ) ) ;
}
if ( cipher_ctx . active ) {
/* Ciphers are allowed only to source from DMA out. That is filtered above. */
assert ( cipher_ctx . current_src = = src_dma ) ;
cipher_ctx . consumed + = desc_len ;
cipher_ctx . produced = cipher_ctx . blocklength * ( cipher_ctx . consumed / cipher_ctx . blocklength ) ;
if ( cipher_ctx . cbcmode & & ! ( cipher_ctx . tcfg - > flags & CRYPTOCOP_EXPLICIT_IV ) & & cipher_ctx . produced ) {
cipher_ctx . produced - = cipher_ctx . blocklength ; /* Compensate for CBC iv. */
}
DEBUG ( printk ( " cryptocop_setup_dma_list: cipher_ctx producing: consumed=%d, produced=%d, blocklength=%d. \n " , cipher_ctx . consumed , cipher_ctx . produced , cipher_ctx . blocklength ) ) ;
}
/* Setup the DMA out descriptors. */
/* Configure the metadata. */
active_count = 0 ;
eop_needed_count = 0 ;
if ( cipher_ctx . active ) {
+ + active_count ;
if ( cipher_ctx . unit_no = = src_dma ) {
/* mem2mem */
meta_out . ciphsel = src_none ;
} else {
meta_out . ciphsel = cipher_ctx . current_src ;
}
meta_out . ciphconf = cipher_ctx . ciph_conf ;
meta_out . cbcmode = cipher_ctx . cbcmode ;
meta_out . decrypt = cipher_ctx . decrypt ;
DEBUG ( printk ( " set ciphsel=%d ciphconf=%d cbcmode=%d decrypt=%d \n " , meta_out . ciphsel , meta_out . ciphconf , meta_out . cbcmode , meta_out . decrypt ) ) ;
if ( cipher_ctx . done ) + + eop_needed_count ;
} else {
meta_out . ciphsel = src_none ;
}
if ( digest_ctx . active ) {
+ + active_count ;
meta_out . hashsel = digest_ctx . current_src ;
meta_out . hashconf = digest_ctx . hash_conf ;
meta_out . hashmode = 0 ; /* Explicit mode is not used here. */
DEBUG ( printk ( " set hashsel=%d hashconf=%d hashmode=%d \n " , meta_out . hashsel , meta_out . hashconf , meta_out . hashmode ) ) ;
if ( digest_ctx . done ) {
assert ( digest_ctx . pad_descs = = NULL ) ;
failed = create_pad_descriptor ( & digest_ctx , & digest_ctx . pad_descs , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: failed digest pad creation. \n " ) ) ;
goto error_cleanup ;
}
}
} else {
meta_out . hashsel = src_none ;
}
if ( csum_ctx . active ) {
+ + active_count ;
meta_out . csumsel = csum_ctx . current_src ;
if ( csum_ctx . done ) {
assert ( csum_ctx . pad_descs = = NULL ) ;
failed = create_pad_descriptor ( & csum_ctx , & csum_ctx . pad_descs , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: failed csum pad creation. \n " ) ) ;
goto error_cleanup ;
}
}
} else {
meta_out . csumsel = src_none ;
}
DEBUG ( printk ( " cryptocop_setup_dma_list: %d eop needed, %d active units \n " , eop_needed_count , active_count ) ) ;
/* Setup DMA out descriptors for the indata. */
failed = create_output_descriptors ( operation , & iniov_ix , & iniov_offset , desc_len , & current_out_cdesc , & meta_out , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: create_output_descriptors %d \n " , failed ) ) ;
goto error_cleanup ;
}
/* Setup out EOP. If there are active units that are not done here they cannot get an EOP
* so we ust setup a zero length descriptor to DMA to signal EOP only to done units .
* If there is a pad descriptor EOP for the padded unit will be EOPed by it .
*/
assert ( active_count > = eop_needed_count ) ;
assert ( ( eop_needed_count = = 0 ) | | ( eop_needed_count = = 1 ) ) ;
if ( eop_needed_count ) {
/* This means that the bulk operation (cipeher/m2m) is terminated. */
if ( active_count > 1 ) {
/* Use zero length EOP descriptor. */
struct cryptocop_dma_desc * ed = alloc_cdesc ( alloc_flag ) ;
struct strcop_meta_out ed_mo = { 0 } ;
if ( ! ed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: alloc EOP descriptor for cipher \n " ) ) ;
failed = - ENOMEM ;
goto error_cleanup ;
}
assert ( cipher_ctx . active & & cipher_ctx . done ) ;
if ( cipher_ctx . unit_no = = src_dma ) {
/* mem2mem */
ed_mo . ciphsel = src_none ;
} else {
ed_mo . ciphsel = cipher_ctx . current_src ;
}
ed_mo . ciphconf = cipher_ctx . ciph_conf ;
ed_mo . cbcmode = cipher_ctx . cbcmode ;
ed_mo . decrypt = cipher_ctx . decrypt ;
ed - > free_buf = NULL ;
ed - > dma_descr - > wait = 1 ;
ed - > dma_descr - > out_eop = 1 ;
ed - > dma_descr - > buf = ( char * ) virt_to_phys ( & ed ) ; /* Use any valid physical address for zero length descriptor. */
ed - > dma_descr - > after = ed - > dma_descr - > buf ;
ed - > dma_descr - > md = REG_TYPE_CONV ( unsigned short int , struct strcop_meta_out , ed_mo ) ;
current_out_cdesc - > next = ed ;
current_out_cdesc = ed ;
} else {
/* Set EOP in the current out descriptor since the only active module is
* the one needing the EOP . */
current_out_cdesc - > dma_descr - > out_eop = 1 ;
}
}
if ( cipher_ctx . done & & cipher_ctx . active ) cipher_ctx . active = 0 ;
if ( digest_ctx . done & & digest_ctx . active ) digest_ctx . active = 0 ;
if ( csum_ctx . done & & csum_ctx . active ) csum_ctx . active = 0 ;
indata_ix + = odsc - > length ;
odsc = odsc - > next ;
} /* while (odsc) */ /* Process descriptors. */
DEBUG ( printk ( " cryptocop_setup_dma_list: done parsing operation descriptors \n " ) ) ;
if ( cipher_ctx . tcfg & & ( cipher_ctx . active | | ! cipher_ctx . done ) ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: cipher operation not terminated. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( digest_ctx . tcfg & & ( digest_ctx . active | | ! digest_ctx . done ) ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: digest operation not terminated. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
if ( csum_ctx . tcfg & & ( csum_ctx . active | | ! csum_ctx . done ) ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: csum operation not terminated. \n " ) ) ;
failed = - EINVAL ;
goto error_cleanup ;
}
failed = append_input_descriptors ( operation , & current_in_cdesc , & current_out_cdesc , & cipher_ctx , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: append_input_descriptors cipher_ctx %d \n " , failed ) ) ;
goto error_cleanup ;
}
failed = append_input_descriptors ( operation , & current_in_cdesc , & current_out_cdesc , & digest_ctx , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: append_input_descriptors cipher_ctx %d \n " , failed ) ) ;
goto error_cleanup ;
}
failed = append_input_descriptors ( operation , & current_in_cdesc , & current_out_cdesc , & csum_ctx , alloc_flag ) ;
if ( failed ) {
DEBUG_API ( printk ( " cryptocop_setup_dma_list: append_input_descriptors cipher_ctx %d \n " , failed ) ) ;
goto error_cleanup ;
}
DEBUG ( printk ( " cryptocop_setup_dma_list: int_op=0x%p, *int_op=0x%p \n " , int_op , * int_op ) ) ;
( * int_op ) - > cdesc_out = out_cdesc_head . next ;
( * int_op ) - > cdesc_in = in_cdesc_head . next ;
DEBUG ( printk ( " cryptocop_setup_dma_list: out_cdesc_head=0x%p in_cdesc_head=0x%p \n " , ( * int_op ) - > cdesc_out , ( * int_op ) - > cdesc_in ) ) ;
setup_descr_chain ( out_cdesc_head . next ) ;
setup_descr_chain ( in_cdesc_head . next ) ;
/* Last but not least: mark the last DMA in descriptor for a INTR and EOL and the the
* last DMA out descriptor for EOL .
*/
current_in_cdesc - > dma_descr - > intr = 1 ;
current_in_cdesc - > dma_descr - > eol = 1 ;
current_out_cdesc - > dma_descr - > eol = 1 ;
/* Setup DMA contexts. */
( * int_op ) - > ctx_out . next = NULL ;
( * int_op ) - > ctx_out . eol = 1 ;
( * int_op ) - > ctx_out . intr = 0 ;
( * int_op ) - > ctx_out . store_mode = 0 ;
( * int_op ) - > ctx_out . en = 0 ;
( * int_op ) - > ctx_out . dis = 0 ;
( * int_op ) - > ctx_out . md0 = 0 ;
( * int_op ) - > ctx_out . md1 = 0 ;
( * int_op ) - > ctx_out . md2 = 0 ;
( * int_op ) - > ctx_out . md3 = 0 ;
( * int_op ) - > ctx_out . md4 = 0 ;
( * int_op ) - > ctx_out . saved_data = ( dma_descr_data * ) virt_to_phys ( ( * int_op ) - > cdesc_out - > dma_descr ) ;
( * int_op ) - > ctx_out . saved_data_buf = ( * int_op ) - > cdesc_out - > dma_descr - > buf ; /* Already physical address. */
( * int_op ) - > ctx_in . next = NULL ;
( * int_op ) - > ctx_in . eol = 1 ;
( * int_op ) - > ctx_in . intr = 0 ;
( * int_op ) - > ctx_in . store_mode = 0 ;
( * int_op ) - > ctx_in . en = 0 ;
( * int_op ) - > ctx_in . dis = 0 ;
( * int_op ) - > ctx_in . md0 = 0 ;
( * int_op ) - > ctx_in . md1 = 0 ;
( * int_op ) - > ctx_in . md2 = 0 ;
( * int_op ) - > ctx_in . md3 = 0 ;
( * int_op ) - > ctx_in . md4 = 0 ;
( * int_op ) - > ctx_in . saved_data = ( dma_descr_data * ) virt_to_phys ( ( * int_op ) - > cdesc_in - > dma_descr ) ;
( * int_op ) - > ctx_in . saved_data_buf = ( * int_op ) - > cdesc_in - > dma_descr - > buf ; /* Already physical address. */
DEBUG ( printk ( " cryptocop_setup_dma_list: done \n " ) ) ;
return 0 ;
error_cleanup :
{
/* Free all allocated resources. */
struct cryptocop_dma_desc * tmp_cdesc ;
while ( digest_ctx . pad_descs ) {
tmp_cdesc = digest_ctx . pad_descs - > next ;
free_cdesc ( digest_ctx . pad_descs ) ;
digest_ctx . pad_descs = tmp_cdesc ;
}
while ( csum_ctx . pad_descs ) {
tmp_cdesc = csum_ctx . pad_descs - > next ;
free_cdesc ( csum_ctx . pad_descs ) ;
csum_ctx . pad_descs = tmp_cdesc ;
}
assert ( cipher_ctx . pad_descs = = NULL ) ; /* The ciphers are never padded. */
if ( * int_op ! = NULL ) delete_internal_operation ( * int_op ) ;
}
DEBUG_API ( printk ( " cryptocop_setup_dma_list: done with error %d \n " , failed ) ) ;
return failed ;
}
static void delete_internal_operation ( struct cryptocop_int_operation * iop )
{
void * ptr = iop - > alloc_ptr ;
struct cryptocop_dma_desc * cd = iop - > cdesc_out ;
struct cryptocop_dma_desc * next ;
DEBUG ( printk ( " delete_internal_operation: iop=0x%p, alloc_ptr=0x%p \n " , iop , ptr ) ) ;
while ( cd ) {
next = cd - > next ;
free_cdesc ( cd ) ;
cd = next ;
}
cd = iop - > cdesc_in ;
while ( cd ) {
next = cd - > next ;
free_cdesc ( cd ) ;
cd = next ;
}
kfree ( ptr ) ;
}
# define MD5_MIN_PAD_LENGTH (9)
# define MD5_PAD_LENGTH_FIELD_LENGTH (8)
static int create_md5_pad ( int alloc_flag , unsigned long long hashed_length , char * * pad , size_t * pad_length )
{
size_t padlen = MD5_BLOCK_LENGTH - ( hashed_length % MD5_BLOCK_LENGTH ) ;
unsigned char * p ;
int i ;
unsigned long long int bit_length = hashed_length < < 3 ;
if ( padlen < MD5_MIN_PAD_LENGTH ) padlen + = MD5_BLOCK_LENGTH ;
p = kmalloc ( padlen , alloc_flag ) ;
if ( ! pad ) return - ENOMEM ;
* p = 0x80 ;
memset ( p + 1 , 0 , padlen - 1 ) ;
DEBUG ( printk ( " create_md5_pad: hashed_length=%lld bits == %lld bytes \n " , bit_length , hashed_length ) ) ;
i = padlen - MD5_PAD_LENGTH_FIELD_LENGTH ;
while ( bit_length ! = 0 ) {
p [ i + + ] = bit_length % 0x100 ;
bit_length > > = 8 ;
}
* pad = ( char * ) p ;
* pad_length = padlen ;
return 0 ;
}
# define SHA1_MIN_PAD_LENGTH (9)
# define SHA1_PAD_LENGTH_FIELD_LENGTH (8)
static int create_sha1_pad ( int alloc_flag , unsigned long long hashed_length , char * * pad , size_t * pad_length )
{
size_t padlen = SHA1_BLOCK_LENGTH - ( hashed_length % SHA1_BLOCK_LENGTH ) ;
unsigned char * p ;
int i ;
unsigned long long int bit_length = hashed_length < < 3 ;
if ( padlen < SHA1_MIN_PAD_LENGTH ) padlen + = SHA1_BLOCK_LENGTH ;
p = kmalloc ( padlen , alloc_flag ) ;
if ( ! pad ) return - ENOMEM ;
* p = 0x80 ;
memset ( p + 1 , 0 , padlen - 1 ) ;
DEBUG ( printk ( " create_sha1_pad: hashed_length=%lld bits == %lld bytes \n " , bit_length , hashed_length ) ) ;
i = padlen - 1 ;
while ( bit_length ! = 0 ) {
p [ i - - ] = bit_length % 0x100 ;
bit_length > > = 8 ;
}
* pad = ( char * ) p ;
* pad_length = padlen ;
return 0 ;
}
static int transform_ok ( struct cryptocop_transform_init * tinit )
{
switch ( tinit - > alg ) {
case cryptocop_alg_csum :
switch ( tinit - > csum_mode ) {
case cryptocop_csum_le :
case cryptocop_csum_be :
break ;
default :
DEBUG_API ( printk ( " transform_ok: Bad mode set for csum transform \n " ) ) ;
return - EINVAL ;
}
case cryptocop_alg_mem2mem :
case cryptocop_alg_md5 :
case cryptocop_alg_sha1 :
if ( tinit - > keylen ! = 0 ) {
DEBUG_API ( printk ( " transform_ok: non-zero keylength, %d, for a digest/csum algorithm \n " , tinit - > keylen ) ) ;
return - EINVAL ; /* This check is a bit strict. */
}
break ;
case cryptocop_alg_des :
if ( tinit - > keylen ! = 64 ) {
DEBUG_API ( printk ( " transform_ok: keylen %d invalid for DES \n " , tinit - > keylen ) ) ;
return - EINVAL ;
}
break ;
case cryptocop_alg_3des :
if ( tinit - > keylen ! = 192 ) {
DEBUG_API ( printk ( " transform_ok: keylen %d invalid for 3DES \n " , tinit - > keylen ) ) ;
return - EINVAL ;
}
break ;
case cryptocop_alg_aes :
if ( tinit - > keylen ! = 128 & & tinit - > keylen ! = 192 & & tinit - > keylen ! = 256 ) {
DEBUG_API ( printk ( " transform_ok: keylen %d invalid for AES \n " , tinit - > keylen ) ) ;
return - EINVAL ;
}
break ;
case cryptocop_no_alg :
default :
DEBUG_API ( printk ( " transform_ok: no such algorithm %d \n " , tinit - > alg ) ) ;
return - EINVAL ;
}
switch ( tinit - > alg ) {
case cryptocop_alg_des :
case cryptocop_alg_3des :
case cryptocop_alg_aes :
if ( tinit - > cipher_mode ! = cryptocop_cipher_mode_ecb & & tinit - > cipher_mode ! = cryptocop_cipher_mode_cbc ) return - EINVAL ;
default :
break ;
}
return 0 ;
}
int cryptocop_new_session ( cryptocop_session_id * sid , struct cryptocop_transform_init * tinit , int alloc_flag )
{
struct cryptocop_session * sess ;
struct cryptocop_transform_init * tfrm_in = tinit ;
struct cryptocop_transform_init * tmp_in ;
int no_tfrms = 0 ;
int i ;
unsigned long int flags ;
init_stream_coprocessor ( ) ; /* For safety if we are called early */
while ( tfrm_in ) {
int err ;
+ + no_tfrms ;
if ( ( err = transform_ok ( tfrm_in ) ) ) {
DEBUG_API ( printk ( " cryptocop_new_session, bad transform \n " ) ) ;
return err ;
}
tfrm_in = tfrm_in - > next ;
}
if ( 0 = = no_tfrms ) {
DEBUG_API ( printk ( " cryptocop_new_session, no transforms specified \n " ) ) ;
return - EINVAL ;
}
sess = kmalloc ( sizeof ( struct cryptocop_session ) , alloc_flag ) ;
if ( ! sess ) {
DEBUG_API ( printk ( " cryptocop_new_session, kmalloc cryptocop_session \n " ) ) ;
return - ENOMEM ;
}
sess - > tfrm_ctx = kmalloc ( no_tfrms * sizeof ( struct cryptocop_transform_ctx ) , alloc_flag ) ;
if ( ! sess - > tfrm_ctx ) {
DEBUG_API ( printk ( " cryptocop_new_session, kmalloc cryptocop_transform_ctx \n " ) ) ;
kfree ( sess ) ;
return - ENOMEM ;
}
tfrm_in = tinit ;
for ( i = 0 ; i < no_tfrms ; i + + ) {
tmp_in = tfrm_in - > next ;
while ( tmp_in ) {
if ( tmp_in - > tid = = tfrm_in - > tid ) {
DEBUG_API ( printk ( " cryptocop_new_session, duplicate transform ids \n " ) ) ;
kfree ( sess - > tfrm_ctx ) ;
kfree ( sess ) ;
return - EINVAL ;
}
tmp_in = tmp_in - > next ;
}
memcpy ( & sess - > tfrm_ctx [ i ] . init , tfrm_in , sizeof ( struct cryptocop_transform_init ) ) ;
sess - > tfrm_ctx [ i ] . dec_key_set = 0 ;
sess - > tfrm_ctx [ i ] . next = & sess - > tfrm_ctx [ i ] + 1 ;
tfrm_in = tfrm_in - > next ;
}
sess - > tfrm_ctx [ i - 1 ] . next = NULL ;
spin_lock_irqsave ( & cryptocop_sessions_lock , flags ) ;
sess - > sid = next_sid ;
next_sid + + ;
/* TODO If we are really paranoid we should do duplicate check to handle sid wraparound.
* OTOH 2 ^ 64 is a really large number of session . */
if ( next_sid = = 0 ) next_sid = 1 ;
/* Prepend to session list. */
sess - > next = cryptocop_sessions ;
cryptocop_sessions = sess ;
spin_unlock_irqrestore ( & cryptocop_sessions_lock , flags ) ;
* sid = sess - > sid ;
return 0 ;
}
int cryptocop_free_session ( cryptocop_session_id sid )
{
struct cryptocop_transform_ctx * tc ;
struct cryptocop_session * sess = NULL ;
struct cryptocop_session * psess = NULL ;
unsigned long int flags ;
int i ;
LIST_HEAD ( remove_list ) ;
struct list_head * node , * tmp ;
struct cryptocop_prio_job * pj ;
DEBUG ( printk ( " cryptocop_free_session: sid=%lld \n " , sid ) ) ;
spin_lock_irqsave ( & cryptocop_sessions_lock , flags ) ;
sess = cryptocop_sessions ;
while ( sess & & sess - > sid ! = sid ) {
psess = sess ;
sess = sess - > next ;
}
if ( sess ) {
if ( psess ) {
psess - > next = sess - > next ;
} else {
cryptocop_sessions = sess - > next ;
}
}
spin_unlock_irqrestore ( & cryptocop_sessions_lock , flags ) ;
if ( ! sess ) return - EINVAL ;
/* Remove queued jobs. */
spin_lock_irqsave ( & cryptocop_job_queue_lock , flags ) ;
for ( i = 0 ; i < cryptocop_prio_no_prios ; i + + ) {
if ( ! list_empty ( & ( cryptocop_job_queues [ i ] . jobs ) ) ) {
list_for_each_safe ( node , tmp , & ( cryptocop_job_queues [ i ] . jobs ) ) {
pj = list_entry ( node , struct cryptocop_prio_job , node ) ;
if ( pj - > oper - > sid = = sid ) {
list_move_tail ( node , & remove_list ) ;
}
}
}
}
spin_unlock_irqrestore ( & cryptocop_job_queue_lock , flags ) ;
list_for_each_safe ( node , tmp , & remove_list ) {
list_del ( node ) ;
pj = list_entry ( node , struct cryptocop_prio_job , node ) ;
pj - > oper - > operation_status = - EAGAIN ; /* EAGAIN is not ideal for job/session terminated but it's the best choice I know of. */
DEBUG ( printk ( " cryptocop_free_session: pj=0x%p, pj->oper=0x%p, pj->iop=0x%p \n " , pj , pj - > oper , pj - > iop ) ) ;
pj - > oper - > cb ( pj - > oper , pj - > oper - > cb_data ) ;
delete_internal_operation ( pj - > iop ) ;
kfree ( pj ) ;
}
tc = sess - > tfrm_ctx ;
/* Erase keying data. */
while ( tc ) {
DEBUG ( printk ( " cryptocop_free_session: memset keys, tfrm id=%d \n " , tc - > init . tid ) ) ;
memset ( tc - > init . key , 0xff , CRYPTOCOP_MAX_KEY_LENGTH ) ;
memset ( tc - > dec_key , 0xff , CRYPTOCOP_MAX_KEY_LENGTH ) ;
tc = tc - > next ;
}
kfree ( sess - > tfrm_ctx ) ;
kfree ( sess ) ;
return 0 ;
}
static struct cryptocop_session * get_session ( cryptocop_session_id sid )
{
struct cryptocop_session * sess ;
unsigned long int flags ;
spin_lock_irqsave ( & cryptocop_sessions_lock , flags ) ;
sess = cryptocop_sessions ;
while ( sess & & ( sess - > sid ! = sid ) ) {
sess = sess - > next ;
}
spin_unlock_irqrestore ( & cryptocop_sessions_lock , flags ) ;
return sess ;
}
static struct cryptocop_transform_ctx * get_transform_ctx ( struct cryptocop_session * sess , cryptocop_tfrm_id tid )
{
struct cryptocop_transform_ctx * tc = sess - > tfrm_ctx ;
DEBUG ( printk ( " get_transform_ctx, sess=0x%p, tid=%d \n " , sess , tid ) ) ;
assert ( sess ! = NULL ) ;
while ( tc & & tc - > init . tid ! = tid ) {
DEBUG ( printk ( " tc=0x%p, tc->next=0x%p \n " , tc , tc - > next ) ) ;
tc = tc - > next ;
}
DEBUG ( printk ( " get_transform_ctx, returning tc=0x%p \n " , tc ) ) ;
return tc ;
}
/* The AES s-transform matrix (s-box). */
static const u8 aes_sbox [ 256 ] = {
99 , 124 , 119 , 123 , 242 , 107 , 111 , 197 , 48 , 1 , 103 , 43 , 254 , 215 , 171 , 118 ,
202 , 130 , 201 , 125 , 250 , 89 , 71 , 240 , 173 , 212 , 162 , 175 , 156 , 164 , 114 , 192 ,
183 , 253 , 147 , 38 , 54 , 63 , 247 , 204 , 52 , 165 , 229 , 241 , 113 , 216 , 49 , 21 ,
4 , 199 , 35 , 195 , 24 , 150 , 5 , 154 , 7 , 18 , 128 , 226 , 235 , 39 , 178 , 117 ,
9 , 131 , 44 , 26 , 27 , 110 , 90 , 160 , 82 , 59 , 214 , 179 , 41 , 227 , 47 , 132 ,
83 , 209 , 0 , 237 , 32 , 252 , 177 , 91 , 106 , 203 , 190 , 57 , 74 , 76 , 88 , 207 ,
208 , 239 , 170 , 251 , 67 , 77 , 51 , 133 , 69 , 249 , 2 , 127 , 80 , 60 , 159 , 168 ,
81 , 163 , 64 , 143 , 146 , 157 , 56 , 245 , 188 , 182 , 218 , 33 , 16 , 255 , 243 , 210 ,
205 , 12 , 19 , 236 , 95 , 151 , 68 , 23 , 196 , 167 , 126 , 61 , 100 , 93 , 25 , 115 ,
96 , 129 , 79 , 220 , 34 , 42 , 144 , 136 , 70 , 238 , 184 , 20 , 222 , 94 , 11 , 219 ,
224 , 50 , 58 , 10 , 73 , 6 , 36 , 92 , 194 , 211 , 172 , 98 , 145 , 149 , 228 , 121 ,
231 , 200 , 55 , 109 , 141 , 213 , 78 , 169 , 108 , 86 , 244 , 234 , 101 , 122 , 174 , 8 ,
186 , 120 , 37 , 46 , 28 , 166 , 180 , 198 , 232 , 221 , 116 , 31 , 75 , 189 , 139 , 138 ,
112 , 62 , 181 , 102 , 72 , 3 , 246 , 14 , 97 , 53 , 87 , 185 , 134 , 193 , 29 , 158 ,
225 , 248 , 152 , 17 , 105 , 217 , 142 , 148 , 155 , 30 , 135 , 233 , 206 , 85 , 40 , 223 ,
140 , 161 , 137 , 13 , 191 , 230 , 66 , 104 , 65 , 153 , 45 , 15 , 176 , 84 , 187 , 22
} ;
/* AES has a 32 bit word round constants for each round in the
* key schedule . round_constant [ i ] is really Rcon [ i + 1 ] in FIPS187 .
*/
static u32 round_constant [ 11 ] = {
0x01000000 , 0x02000000 , 0x04000000 , 0x08000000 ,
0x10000000 , 0x20000000 , 0x40000000 , 0x80000000 ,
0x1B000000 , 0x36000000 , 0x6C000000
} ;
/* Apply the s-box to each of the four occtets in w. */
static u32 aes_ks_subword ( const u32 w )
{
u8 bytes [ 4 ] ;
* ( u32 * ) ( & bytes [ 0 ] ) = w ;
bytes [ 0 ] = aes_sbox [ bytes [ 0 ] ] ;
bytes [ 1 ] = aes_sbox [ bytes [ 1 ] ] ;
bytes [ 2 ] = aes_sbox [ bytes [ 2 ] ] ;
bytes [ 3 ] = aes_sbox [ bytes [ 3 ] ] ;
return * ( u32 * ) ( & bytes [ 0 ] ) ;
}
/* The encrypt (forward) Rijndael key schedule algorithm pseudo code:
* ( Note that AES words are 32 bit long )
*
* KeyExpansion ( byte key [ 4 * Nk ] , word w [ Nb * ( Nr + 1 ) ] , Nk ) {
* word temp
* i = 0
* while ( i < Nk ) {
* w [ i ] = word ( key [ 4 * i , 4 * i + 1 , 4 * i + 2 , 4 * i + 3 ] )
* i = i + 1
* }
* i = Nk
*
* while ( i < ( Nb * ( Nr + 1 ) ) ) {
* temp = w [ i - 1 ]
* if ( ( i mod Nk ) = = 0 ) {
* temp = SubWord ( RotWord ( temp ) ) xor Rcon [ i / Nk ]
* }
* else if ( ( Nk > 6 ) & & ( ( i mod Nk ) = = 4 ) ) {
* temp = SubWord ( temp )
* }
* w [ i ] = w [ i - Nk ] xor temp
* }
* RotWord ( t ) does a 8 bit cyclic shift left on a 32 bit word .
* SubWord ( t ) applies the AES s - box individually to each octet
* in a 32 bit word .
*
* For AES Nk can have the values 4 , 6 , and 8 ( corresponding to
* values for Nr of 10 , 12 , and 14 ) . Nb is always 4.
*
* To construct w [ i ] , w [ i - 1 ] and w [ i - Nk ] must be
* available . Consequently we must keep a state of the last Nk words
* to be able to create the last round keys .
*/
static void get_aes_decrypt_key ( unsigned char * dec_key , const unsigned char * key , unsigned int keylength )
{
u32 temp ;
u32 w_ring [ 8 ] ; /* nk is max 8, use elements 0..(nk - 1) as a ringbuffer */
u8 w_last_ix ;
int i ;
u8 nr , nk ;
switch ( keylength ) {
case 128 :
nk = 4 ;
nr = 10 ;
break ;
case 192 :
nk = 6 ;
nr = 12 ;
break ;
case 256 :
nk = 8 ;
nr = 14 ;
break ;
default :
panic ( " stream co-processor: bad aes key length in get_aes_decrypt_key \n " ) ;
} ;
/* Need to do host byte order correction here since key is byte oriented and the
* kx algorithm is word ( u32 ) oriented . */
for ( i = 0 ; i < nk ; i + = 1 ) {
w_ring [ i ] = be32_to_cpu ( * ( u32 * ) & key [ 4 * i ] ) ;
}
i = ( int ) nk ;
w_last_ix = i - 1 ;
while ( i < ( 4 * ( nr + 2 ) ) ) {
temp = w_ring [ w_last_ix ] ;
if ( ! ( i % nk ) ) {
/* RotWord(temp) */
temp = ( temp < < 8 ) | ( temp > > 24 ) ;
temp = aes_ks_subword ( temp ) ;
temp ^ = round_constant [ i / nk - 1 ] ;
} else if ( ( nk > 6 ) & & ( ( i % nk ) = = 4 ) ) {
temp = aes_ks_subword ( temp ) ;
}
w_last_ix = ( w_last_ix + 1 ) % nk ; /* This is the same as (i-Nk) mod Nk */
temp ^ = w_ring [ w_last_ix ] ;
w_ring [ w_last_ix ] = temp ;
/* We need the round keys for round Nr+1 and Nr+2 (round key
* Nr + 2 is the round key beyond the last one used when
* encrypting ) . Rounds are numbered starting from 0 , Nr = 10
* implies 11 rounds are used in encryption / decryption .
*/
if ( i > = ( 4 * nr ) ) {
/* Need to do host byte order correction here, the key
* is byte oriented . */
* ( u32 * ) dec_key = cpu_to_be32 ( temp ) ;
dec_key + = 4 ;
}
+ + i ;
}
}
/**** Job/operation management. ****/
int cryptocop_job_queue_insert_csum ( struct cryptocop_operation * operation )
{
return cryptocop_job_queue_insert ( cryptocop_prio_kernel_csum , operation ) ;
}
int cryptocop_job_queue_insert_crypto ( struct cryptocop_operation * operation )
{
return cryptocop_job_queue_insert ( cryptocop_prio_kernel , operation ) ;
}
int cryptocop_job_queue_insert_user_job ( struct cryptocop_operation * operation )
{
return cryptocop_job_queue_insert ( cryptocop_prio_user , operation ) ;
}
static int cryptocop_job_queue_insert ( cryptocop_queue_priority prio , struct cryptocop_operation * operation )
{
int ret ;
struct cryptocop_prio_job * pj = NULL ;
unsigned long int flags ;
DEBUG ( printk ( " cryptocop_job_queue_insert(%d, 0x%p) \n " , prio , operation ) ) ;
if ( ! operation | | ! operation - > cb ) {
DEBUG_API ( printk ( " cryptocop_job_queue_insert oper=0x%p, NULL operation or callback \n " , operation ) ) ;
return - EINVAL ;
}
if ( ( ret = cryptocop_job_setup ( & pj , operation ) ) ! = 0 ) {
DEBUG_API ( printk ( " cryptocop_job_queue_insert: job setup failed \n " ) ) ;
return ret ;
}
assert ( pj ! = NULL ) ;
spin_lock_irqsave ( & cryptocop_job_queue_lock , flags ) ;
list_add_tail ( & pj - > node , & cryptocop_job_queues [ prio ] . jobs ) ;
spin_unlock_irqrestore ( & cryptocop_job_queue_lock , flags ) ;
/* Make sure a job is running */
cryptocop_start_job ( ) ;
return 0 ;
}
static void cryptocop_do_tasklet ( unsigned long unused ) ;
DECLARE_TASKLET ( cryptocop_tasklet , cryptocop_do_tasklet , 0 ) ;
static void cryptocop_do_tasklet ( unsigned long unused )
{
struct list_head * node ;
struct cryptocop_prio_job * pj = NULL ;
unsigned long flags ;
DEBUG ( printk ( " cryptocop_do_tasklet: entering \n " ) ) ;
do {
spin_lock_irqsave ( & cryptocop_completed_jobs_lock , flags ) ;
if ( ! list_empty ( & cryptocop_completed_jobs ) ) {
node = cryptocop_completed_jobs . next ;
list_del ( node ) ;
pj = list_entry ( node , struct cryptocop_prio_job , node ) ;
} else {
pj = NULL ;
}
spin_unlock_irqrestore ( & cryptocop_completed_jobs_lock , flags ) ;
if ( pj ) {
assert ( pj - > oper ! = NULL ) ;
/* Notify consumer of operation completeness. */
DEBUG ( printk ( " cryptocop_do_tasklet: callback 0x%p, data 0x%p \n " , pj - > oper - > cb , pj - > oper - > cb_data ) ) ;
pj - > oper - > operation_status = 0 ; /* Job is completed. */
pj - > oper - > cb ( pj - > oper , pj - > oper - > cb_data ) ;
delete_internal_operation ( pj - > iop ) ;
kfree ( pj ) ;
}
} while ( pj ! = NULL ) ;
DEBUG ( printk ( " cryptocop_do_tasklet: exiting \n " ) ) ;
}
static irqreturn_t
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dma_done_interrupt ( int irq , void * dev_id )
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{
struct cryptocop_prio_job * done_job ;
reg_dma_rw_ack_intr ack_intr = {
. data = 1 ,
} ;
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REG_WR ( dma , IN_DMA_INST , rw_ack_intr , ack_intr ) ;
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DEBUG ( printk ( " cryptocop DMA done \n " ) ) ;
spin_lock ( & running_job_lock ) ;
if ( cryptocop_running_job = = NULL ) {
printk ( " stream co-processor got interrupt when not busy \n " ) ;
spin_unlock ( & running_job_lock ) ;
return IRQ_HANDLED ;
}
done_job = cryptocop_running_job ;
cryptocop_running_job = NULL ;
spin_unlock ( & running_job_lock ) ;
/* Start processing a job. */
if ( ! spin_trylock ( & cryptocop_process_lock ) ) {
DEBUG ( printk ( " cryptocop irq handler, not starting a job \n " ) ) ;
} else {
cryptocop_start_job ( ) ;
spin_unlock ( & cryptocop_process_lock ) ;
}
done_job - > oper - > operation_status = 0 ; /* Job is completed. */
if ( done_job - > oper - > fast_callback ) {
/* This operation wants callback from interrupt. */
done_job - > oper - > cb ( done_job - > oper , done_job - > oper - > cb_data ) ;
delete_internal_operation ( done_job - > iop ) ;
kfree ( done_job ) ;
} else {
spin_lock ( & cryptocop_completed_jobs_lock ) ;
list_add_tail ( & ( done_job - > node ) , & cryptocop_completed_jobs ) ;
spin_unlock ( & cryptocop_completed_jobs_lock ) ;
tasklet_schedule ( & cryptocop_tasklet ) ;
}
DEBUG ( printk ( " cryptocop leave irq handler \n " ) ) ;
return IRQ_HANDLED ;
}
/* Setup interrupts and DMA channels. */
static int init_cryptocop ( void )
{
unsigned long flags ;
reg_dma_rw_cfg dma_cfg = { . en = 1 } ;
reg_dma_rw_intr_mask intr_mask_in = { . data = regk_dma_yes } ; /* Only want descriptor interrupts from the DMA in channel. */
reg_dma_rw_ack_intr ack_intr = { . data = 1 , . in_eop = 1 } ;
reg_strcop_rw_cfg strcop_cfg = {
. ipend = regk_strcop_little ,
. td1 = regk_strcop_e ,
. td2 = regk_strcop_d ,
. td3 = regk_strcop_e ,
. ignore_sync = 0 ,
. en = 1
} ;
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if ( request_irq ( DMA_IRQ , dma_done_interrupt , 0 ,
" stream co-processor DMA " , NULL ) )
panic ( " request_irq stream co-processor irq dma9 " ) ;
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( void ) crisv32_request_dma ( OUT_DMA , " strcop " , DMA_PANIC_ON_ERROR ,
0 , dma_strp ) ;
( void ) crisv32_request_dma ( IN_DMA , " strcop " , DMA_PANIC_ON_ERROR ,
0 , dma_strp ) ;
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local_irq_save ( flags ) ;
/* Reset and enable the cryptocop. */
strcop_cfg . en = 0 ;
REG_WR ( strcop , regi_strcop , rw_cfg , strcop_cfg ) ;
strcop_cfg . en = 1 ;
REG_WR ( strcop , regi_strcop , rw_cfg , strcop_cfg ) ;
/* Enable DMAs. */
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REG_WR ( dma , IN_DMA_INST , rw_cfg , dma_cfg ) ; /* input DMA */
REG_WR ( dma , OUT_DMA_INST , rw_cfg , dma_cfg ) ; /* output DMA */
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/* Set up wordsize = 4 for DMAs. */
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DMA_WR_CMD ( OUT_DMA_INST , regk_dma_set_w_size4 ) ;
DMA_WR_CMD ( IN_DMA_INST , regk_dma_set_w_size4 ) ;
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/* Enable interrupts. */
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REG_WR ( dma , IN_DMA_INST , rw_intr_mask , intr_mask_in ) ;
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/* Clear intr ack. */
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REG_WR ( dma , IN_DMA_INST , rw_ack_intr , ack_intr ) ;
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local_irq_restore ( flags ) ;
return 0 ;
}
/* Free used cryptocop hw resources (interrupt and DMA channels). */
static void release_cryptocop ( void )
{
unsigned long flags ;
reg_dma_rw_cfg dma_cfg = { . en = 0 } ;
reg_dma_rw_intr_mask intr_mask_in = { 0 } ;
reg_dma_rw_ack_intr ack_intr = { . data = 1 , . in_eop = 1 } ;
local_irq_save ( flags ) ;
/* Clear intr ack. */
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REG_WR ( dma , IN_DMA_INST , rw_ack_intr , ack_intr ) ;
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/* Disable DMAs. */
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REG_WR ( dma , IN_DMA_INST , rw_cfg , dma_cfg ) ; /* input DMA */
REG_WR ( dma , OUT_DMA_INST , rw_cfg , dma_cfg ) ; /* output DMA */
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/* Disable interrupts. */
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REG_WR ( dma , IN_DMA_INST , rw_intr_mask , intr_mask_in ) ;
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local_irq_restore ( flags ) ;
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free_irq ( DMA_IRQ , NULL ) ;
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( void ) crisv32_free_dma ( OUT_DMA ) ;
( void ) crisv32_free_dma ( IN_DMA ) ;
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}
/* Init job queue. */
static int cryptocop_job_queue_init ( void )
{
int i ;
INIT_LIST_HEAD ( & cryptocop_completed_jobs ) ;
for ( i = 0 ; i < cryptocop_prio_no_prios ; i + + ) {
cryptocop_job_queues [ i ] . prio = ( cryptocop_queue_priority ) i ;
INIT_LIST_HEAD ( & cryptocop_job_queues [ i ] . jobs ) ;
}
return 0 ;
}
static void cryptocop_job_queue_close ( void )
{
struct list_head * node , * tmp ;
struct cryptocop_prio_job * pj = NULL ;
unsigned long int process_flags , flags ;
int i ;
/* FIXME: This is as yet untested code. */
/* Stop strcop from getting an operation to process while we are closing the
module . */
spin_lock_irqsave ( & cryptocop_process_lock , process_flags ) ;
/* Empty the job queue. */
for ( i = 0 ; i < cryptocop_prio_no_prios ; i + + ) {
if ( ! list_empty ( & ( cryptocop_job_queues [ i ] . jobs ) ) ) {
list_for_each_safe ( node , tmp , & ( cryptocop_job_queues [ i ] . jobs ) ) {
pj = list_entry ( node , struct cryptocop_prio_job , node ) ;
list_del ( node ) ;
/* Call callback to notify consumer of job removal. */
DEBUG ( printk ( " cryptocop_job_queue_close: callback 0x%p, data 0x%p \n " , pj - > oper - > cb , pj - > oper - > cb_data ) ) ;
pj - > oper - > operation_status = - EINTR ; /* Job is terminated without completion. */
pj - > oper - > cb ( pj - > oper , pj - > oper - > cb_data ) ;
delete_internal_operation ( pj - > iop ) ;
kfree ( pj ) ;
}
}
}
spin_unlock_irqrestore ( & cryptocop_process_lock , process_flags ) ;
/* Remove the running job, if any. */
spin_lock_irqsave ( & running_job_lock , flags ) ;
if ( cryptocop_running_job ) {
reg_strcop_rw_cfg rw_cfg ;
reg_dma_rw_cfg dma_out_cfg , dma_in_cfg ;
/* Stop DMA. */
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dma_out_cfg = REG_RD ( dma , OUT_DMA_INST , rw_cfg ) ;
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dma_out_cfg . en = regk_dma_no ;
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REG_WR ( dma , OUT_DMA_INST , rw_cfg , dma_out_cfg ) ;
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dma_in_cfg = REG_RD ( dma , IN_DMA_INST , rw_cfg ) ;
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dma_in_cfg . en = regk_dma_no ;
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REG_WR ( dma , IN_DMA_INST , rw_cfg , dma_in_cfg ) ;
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/* Disble the cryptocop. */
rw_cfg = REG_RD ( strcop , regi_strcop , rw_cfg ) ;
rw_cfg . en = 0 ;
REG_WR ( strcop , regi_strcop , rw_cfg , rw_cfg ) ;
pj = cryptocop_running_job ;
cryptocop_running_job = NULL ;
/* Call callback to notify consumer of job removal. */
DEBUG ( printk ( " cryptocop_job_queue_close: callback 0x%p, data 0x%p \n " , pj - > oper - > cb , pj - > oper - > cb_data ) ) ;
pj - > oper - > operation_status = - EINTR ; /* Job is terminated without completion. */
pj - > oper - > cb ( pj - > oper , pj - > oper - > cb_data ) ;
delete_internal_operation ( pj - > iop ) ;
kfree ( pj ) ;
}
spin_unlock_irqrestore ( & running_job_lock , flags ) ;
/* Remove completed jobs, if any. */
spin_lock_irqsave ( & cryptocop_completed_jobs_lock , flags ) ;
list_for_each_safe ( node , tmp , & cryptocop_completed_jobs ) {
pj = list_entry ( node , struct cryptocop_prio_job , node ) ;
list_del ( node ) ;
/* Call callback to notify consumer of job removal. */
DEBUG ( printk ( " cryptocop_job_queue_close: callback 0x%p, data 0x%p \n " , pj - > oper - > cb , pj - > oper - > cb_data ) ) ;
pj - > oper - > operation_status = - EINTR ; /* Job is terminated without completion. */
pj - > oper - > cb ( pj - > oper , pj - > oper - > cb_data ) ;
delete_internal_operation ( pj - > iop ) ;
kfree ( pj ) ;
}
spin_unlock_irqrestore ( & cryptocop_completed_jobs_lock , flags ) ;
}
static void cryptocop_start_job ( void )
{
int i ;
struct cryptocop_prio_job * pj ;
unsigned long int flags ;
unsigned long int running_job_flags ;
reg_strcop_rw_cfg rw_cfg = { . en = 1 , . ignore_sync = 0 } ;
DEBUG ( printk ( " cryptocop_start_job: entering \n " ) ) ;
spin_lock_irqsave ( & running_job_lock , running_job_flags ) ;
if ( cryptocop_running_job ! = NULL ) {
/* Already running. */
DEBUG ( printk ( " cryptocop_start_job: already running, exit \n " ) ) ;
spin_unlock_irqrestore ( & running_job_lock , running_job_flags ) ;
return ;
}
spin_lock_irqsave ( & cryptocop_job_queue_lock , flags ) ;
/* Check the queues in priority order. */
for ( i = cryptocop_prio_kernel_csum ; ( i < cryptocop_prio_no_prios ) & & list_empty ( & cryptocop_job_queues [ i ] . jobs ) ; i + + ) ;
if ( i = = cryptocop_prio_no_prios ) {
spin_unlock_irqrestore ( & cryptocop_job_queue_lock , flags ) ;
spin_unlock_irqrestore ( & running_job_lock , running_job_flags ) ;
DEBUG ( printk ( " cryptocop_start_job: no jobs to run \n " ) ) ;
return ; /* No jobs to run */
}
DEBUG ( printk ( " starting job for prio %d \n " , i ) ) ;
/* TODO: Do not starve lower priority jobs. Let in a lower
* prio job for every N - th processed higher prio job or some
* other scheduling policy . This could reasonably be
* tweakable since the optimal balance would depend on the
* type of load on the system . */
/* Pull the DMA lists from the job and start the DMA client. */
pj = list_entry ( cryptocop_job_queues [ i ] . jobs . next , struct cryptocop_prio_job , node ) ;
list_del ( & pj - > node ) ;
spin_unlock_irqrestore ( & cryptocop_job_queue_lock , flags ) ;
cryptocop_running_job = pj ;
/* Set config register (3DES and CSUM modes). */
switch ( pj - > iop - > tdes_mode ) {
case cryptocop_3des_eee :
rw_cfg . td1 = regk_strcop_e ;
rw_cfg . td2 = regk_strcop_e ;
rw_cfg . td3 = regk_strcop_e ;
break ;
case cryptocop_3des_eed :
rw_cfg . td1 = regk_strcop_e ;
rw_cfg . td2 = regk_strcop_e ;
rw_cfg . td3 = regk_strcop_d ;
break ;
case cryptocop_3des_ede :
rw_cfg . td1 = regk_strcop_e ;
rw_cfg . td2 = regk_strcop_d ;
rw_cfg . td3 = regk_strcop_e ;
break ;
case cryptocop_3des_edd :
rw_cfg . td1 = regk_strcop_e ;
rw_cfg . td2 = regk_strcop_d ;
rw_cfg . td3 = regk_strcop_d ;
break ;
case cryptocop_3des_dee :
rw_cfg . td1 = regk_strcop_d ;
rw_cfg . td2 = regk_strcop_e ;
rw_cfg . td3 = regk_strcop_e ;
break ;
case cryptocop_3des_ded :
rw_cfg . td1 = regk_strcop_d ;
rw_cfg . td2 = regk_strcop_e ;
rw_cfg . td3 = regk_strcop_d ;
break ;
case cryptocop_3des_dde :
rw_cfg . td1 = regk_strcop_d ;
rw_cfg . td2 = regk_strcop_d ;
rw_cfg . td3 = regk_strcop_e ;
break ;
case cryptocop_3des_ddd :
rw_cfg . td1 = regk_strcop_d ;
rw_cfg . td2 = regk_strcop_d ;
rw_cfg . td3 = regk_strcop_d ;
break ;
default :
DEBUG ( printk ( " cryptocop_setup_dma_list: bad 3DES mode \n " ) ) ;
}
switch ( pj - > iop - > csum_mode ) {
case cryptocop_csum_le :
rw_cfg . ipend = regk_strcop_little ;
break ;
case cryptocop_csum_be :
rw_cfg . ipend = regk_strcop_big ;
break ;
default :
DEBUG ( printk ( " cryptocop_setup_dma_list: bad checksum mode \n " ) ) ;
}
REG_WR ( strcop , regi_strcop , rw_cfg , rw_cfg ) ;
DEBUG ( printk ( " cryptocop_start_job: starting DMA, new cryptocop_running_job=0x%p \n "
" ctx_in: 0x%p, phys: 0x%p \n "
" ctx_out: 0x%p, phys: 0x%p \n " ,
pj ,
& pj - > iop - > ctx_in , ( char * ) virt_to_phys ( & pj - > iop - > ctx_in ) ,
& pj - > iop - > ctx_out , ( char * ) virt_to_phys ( & pj - > iop - > ctx_out ) ) ) ;
/* Start input DMA. */
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flush_dma_context ( & pj - > iop - > ctx_in ) ;
DMA_START_CONTEXT ( IN_DMA_INST , virt_to_phys ( & pj - > iop - > ctx_in ) ) ;
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/* Start output DMA. */
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DMA_START_CONTEXT ( OUT_DMA_INST , virt_to_phys ( & pj - > iop - > ctx_out ) ) ;
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spin_unlock_irqrestore ( & running_job_lock , running_job_flags ) ;
DEBUG ( printk ( " cryptocop_start_job: exiting \n " ) ) ;
}
static int cryptocop_job_setup ( struct cryptocop_prio_job * * pj , struct cryptocop_operation * operation )
{
int err ;
int alloc_flag = operation - > in_interrupt ? GFP_ATOMIC : GFP_KERNEL ;
void * iop_alloc_ptr = NULL ;
* pj = kmalloc ( sizeof ( struct cryptocop_prio_job ) , alloc_flag ) ;
if ( ! * pj ) return - ENOMEM ;
DEBUG ( printk ( " cryptocop_job_setup: operation=0x%p \n " , operation ) ) ;
( * pj ) - > oper = operation ;
DEBUG ( printk ( " cryptocop_job_setup, cb=0x%p cb_data=0x%p \n " , ( * pj ) - > oper - > cb , ( * pj ) - > oper - > cb_data ) ) ;
if ( operation - > use_dmalists ) {
DEBUG ( print_user_dma_lists ( & operation - > list_op ) ) ;
if ( ! operation - > list_op . inlist | | ! operation - > list_op . outlist | | ! operation - > list_op . out_data_buf | | ! operation - > list_op . in_data_buf ) {
DEBUG_API ( printk ( " cryptocop_job_setup: bad indata (use_dmalists) \n " ) ) ;
kfree ( * pj ) ;
return - EINVAL ;
}
iop_alloc_ptr = kmalloc ( DESCR_ALLOC_PAD + sizeof ( struct cryptocop_int_operation ) , alloc_flag ) ;
if ( ! iop_alloc_ptr ) {
DEBUG_API ( printk ( " cryptocop_job_setup: kmalloc cryptocop_int_operation \n " ) ) ;
kfree ( * pj ) ;
return - ENOMEM ;
}
( * pj ) - > iop = ( struct cryptocop_int_operation * ) ( ( ( unsigned long int ) ( iop_alloc_ptr + DESCR_ALLOC_PAD + offsetof ( struct cryptocop_int_operation , ctx_out ) ) & ~ 0x0000001F ) - offsetof ( struct cryptocop_int_operation , ctx_out ) ) ;
DEBUG ( memset ( ( * pj ) - > iop , 0xff , sizeof ( struct cryptocop_int_operation ) ) ) ;
( * pj ) - > iop - > alloc_ptr = iop_alloc_ptr ;
( * pj ) - > iop - > sid = operation - > sid ;
( * pj ) - > iop - > cdesc_out = NULL ;
( * pj ) - > iop - > cdesc_in = NULL ;
( * pj ) - > iop - > tdes_mode = operation - > list_op . tdes_mode ;
( * pj ) - > iop - > csum_mode = operation - > list_op . csum_mode ;
( * pj ) - > iop - > ddesc_out = operation - > list_op . outlist ;
( * pj ) - > iop - > ddesc_in = operation - > list_op . inlist ;
/* Setup DMA contexts. */
( * pj ) - > iop - > ctx_out . next = NULL ;
( * pj ) - > iop - > ctx_out . eol = 1 ;
( * pj ) - > iop - > ctx_out . saved_data = operation - > list_op . outlist ;
( * pj ) - > iop - > ctx_out . saved_data_buf = operation - > list_op . out_data_buf ;
( * pj ) - > iop - > ctx_in . next = NULL ;
( * pj ) - > iop - > ctx_in . eol = 1 ;
( * pj ) - > iop - > ctx_in . saved_data = operation - > list_op . inlist ;
( * pj ) - > iop - > ctx_in . saved_data_buf = operation - > list_op . in_data_buf ;
} else {
if ( ( err = cryptocop_setup_dma_list ( operation , & ( * pj ) - > iop , alloc_flag ) ) ) {
DEBUG_API ( printk ( " cryptocop_job_setup: cryptocop_setup_dma_list failed %d \n " , err ) ) ;
kfree ( * pj ) ;
return err ;
}
}
DEBUG ( print_dma_descriptors ( ( * pj ) - > iop ) ) ;
DEBUG ( printk ( " cryptocop_job_setup, DMA list setup successful \n " ) ) ;
return 0 ;
}
static int cryptocop_open ( struct inode * inode , struct file * filp )
{
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int p = iminor ( inode ) ;
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if ( p ! = CRYPTOCOP_MINOR ) return - EINVAL ;
filp - > private_data = NULL ;
return 0 ;
}
static int cryptocop_release ( struct inode * inode , struct file * filp )
{
struct cryptocop_private * dev = filp - > private_data ;
struct cryptocop_private * dev_next ;
while ( dev ) {
dev_next = dev - > next ;
if ( dev - > sid ! = CRYPTOCOP_SESSION_ID_NONE ) {
( void ) cryptocop_free_session ( dev - > sid ) ;
}
kfree ( dev ) ;
dev = dev_next ;
}
return 0 ;
}
static int cryptocop_ioctl_close_session ( struct inode * inode , struct file * filp ,
unsigned int cmd , unsigned long arg )
{
struct cryptocop_private * dev = filp - > private_data ;
struct cryptocop_private * prev_dev = NULL ;
struct strcop_session_op * sess_op = ( struct strcop_session_op * ) arg ;
struct strcop_session_op sop ;
int err ;
DEBUG ( printk ( " cryptocop_ioctl_close_session \n " ) ) ;
if ( ! access_ok ( VERIFY_READ , sess_op , sizeof ( struct strcop_session_op ) ) )
return - EFAULT ;
err = copy_from_user ( & sop , sess_op , sizeof ( struct strcop_session_op ) ) ;
if ( err ) return - EFAULT ;
while ( dev & & ( dev - > sid ! = sop . ses_id ) ) {
prev_dev = dev ;
dev = dev - > next ;
}
if ( dev ) {
if ( prev_dev ) {
prev_dev - > next = dev - > next ;
} else {
filp - > private_data = dev - > next ;
}
err = cryptocop_free_session ( dev - > sid ) ;
if ( err ) return - EFAULT ;
} else {
DEBUG_API ( printk ( " cryptocop_ioctl_close_session: session %lld not found \n " , sop . ses_id ) ) ;
return - EINVAL ;
}
return 0 ;
}
static void ioctl_process_job_callback ( struct cryptocop_operation * op , void * cb_data )
{
struct ioctl_job_cb_ctx * jc = ( struct ioctl_job_cb_ctx * ) cb_data ;
DEBUG ( printk ( " ioctl_process_job_callback: op=0x%p, cb_data=0x%p \n " , op , cb_data ) ) ;
jc - > processed = 1 ;
wake_up ( & cryptocop_ioc_process_wq ) ;
}
# define CRYPTOCOP_IOCTL_CIPHER_TID (1)
# define CRYPTOCOP_IOCTL_DIGEST_TID (2)
# define CRYPTOCOP_IOCTL_CSUM_TID (3)
static size_t first_cfg_change_ix ( struct strcop_crypto_op * crp_op )
{
size_t ch_ix = 0 ;
if ( crp_op - > do_cipher ) ch_ix = crp_op - > cipher_start ;
if ( crp_op - > do_digest & & ( crp_op - > digest_start < ch_ix ) ) ch_ix = crp_op - > digest_start ;
if ( crp_op - > do_csum & & ( crp_op - > csum_start < ch_ix ) ) ch_ix = crp_op - > csum_start ;
DEBUG ( printk ( " first_cfg_change_ix: ix=%d \n " , ch_ix ) ) ;
return ch_ix ;
}
static size_t next_cfg_change_ix ( struct strcop_crypto_op * crp_op , size_t ix )
{
size_t ch_ix = INT_MAX ;
size_t tmp_ix = 0 ;
if ( crp_op - > do_cipher & & ( ( crp_op - > cipher_start + crp_op - > cipher_len ) > ix ) ) {
if ( crp_op - > cipher_start > ix ) {
ch_ix = crp_op - > cipher_start ;
} else {
ch_ix = crp_op - > cipher_start + crp_op - > cipher_len ;
}
}
if ( crp_op - > do_digest & & ( ( crp_op - > digest_start + crp_op - > digest_len ) > ix ) ) {
if ( crp_op - > digest_start > ix ) {
tmp_ix = crp_op - > digest_start ;
} else {
tmp_ix = crp_op - > digest_start + crp_op - > digest_len ;
}
if ( tmp_ix < ch_ix ) ch_ix = tmp_ix ;
}
if ( crp_op - > do_csum & & ( ( crp_op - > csum_start + crp_op - > csum_len ) > ix ) ) {
if ( crp_op - > csum_start > ix ) {
tmp_ix = crp_op - > csum_start ;
} else {
tmp_ix = crp_op - > csum_start + crp_op - > csum_len ;
}
if ( tmp_ix < ch_ix ) ch_ix = tmp_ix ;
}
if ( ch_ix = = INT_MAX ) ch_ix = ix ;
DEBUG ( printk ( " next_cfg_change_ix prev ix=%d, next ix=%d \n " , ix , ch_ix ) ) ;
return ch_ix ;
}
/* Map map_length bytes from the pages starting on *pageix and *pageoffset to iovecs starting on *iovix.
* Return - 1 for ok , 0 for fail . */
static int map_pages_to_iovec ( struct iovec * iov , int iovlen , int * iovix , struct page * * pages , int nopages , int * pageix , int * pageoffset , int map_length )
{
int tmplen ;
assert ( iov ! = NULL ) ;
assert ( iovix ! = NULL ) ;
assert ( pages ! = NULL ) ;
assert ( pageix ! = NULL ) ;
assert ( pageoffset ! = NULL ) ;
DEBUG ( printk ( " map_pages_to_iovec, map_length=%d, iovlen=%d, *iovix=%d, nopages=%d, *pageix=%d, *pageoffset=%d \n " , map_length , iovlen , * iovix , nopages , * pageix , * pageoffset ) ) ;
while ( map_length > 0 ) {
DEBUG ( printk ( " map_pages_to_iovec, map_length=%d, iovlen=%d, *iovix=%d, nopages=%d, *pageix=%d, *pageoffset=%d \n " , map_length , iovlen , * iovix , nopages , * pageix , * pageoffset ) ) ;
if ( * iovix > = iovlen ) {
DEBUG_API ( printk ( " map_page_to_iovec: *iovix=%d >= iovlen=%d \n " , * iovix , iovlen ) ) ;
return 0 ;
}
if ( * pageix > = nopages ) {
DEBUG_API ( printk ( " map_page_to_iovec: *pageix=%d >= nopages=%d \n " , * pageix , nopages ) ) ;
return 0 ;
}
iov [ * iovix ] . iov_base = ( unsigned char * ) page_address ( pages [ * pageix ] ) + * pageoffset ;
tmplen = PAGE_SIZE - * pageoffset ;
if ( tmplen < map_length ) {
( * pageoffset ) = 0 ;
( * pageix ) + + ;
} else {
tmplen = map_length ;
( * pageoffset ) + = map_length ;
}
DEBUG ( printk ( " mapping %d bytes from page %d (or %d) to iovec %d \n " , tmplen , * pageix , * pageix - 1 , * iovix ) ) ;
iov [ * iovix ] . iov_len = tmplen ;
map_length - = tmplen ;
( * iovix ) + + ;
}
DEBUG ( printk ( " map_page_to_iovec, exit, *iovix=%d \n " , * iovix ) ) ;
return - 1 ;
}
static int cryptocop_ioctl_process ( struct inode * inode , struct file * filp , unsigned int cmd , unsigned long arg )
{
int i ;
struct cryptocop_private * dev = filp - > private_data ;
struct strcop_crypto_op * crp_oper = ( struct strcop_crypto_op * ) arg ;
struct strcop_crypto_op oper = { 0 } ;
int err = 0 ;
struct cryptocop_operation * cop = NULL ;
struct ioctl_job_cb_ctx * jc = NULL ;
struct page * * inpages = NULL ;
struct page * * outpages = NULL ;
int noinpages = 0 ;
int nooutpages = 0 ;
struct cryptocop_desc descs [ 5 ] ; /* Max 5 descriptors are needed, there are three transforms that
* can get connected / disconnected on different places in the indata . */
struct cryptocop_desc_cfg dcfgs [ 5 * 3 ] ;
int desc_ix = 0 ;
int dcfg_ix = 0 ;
struct cryptocop_tfrm_cfg ciph_tcfg = { 0 } ;
struct cryptocop_tfrm_cfg digest_tcfg = { 0 } ;
struct cryptocop_tfrm_cfg csum_tcfg = { 0 } ;
unsigned char * digest_result = NULL ;
int digest_length = 0 ;
int cblocklen = 0 ;
unsigned char csum_result [ CSUM_BLOCK_LENGTH ] ;
struct cryptocop_session * sess ;
int iovlen = 0 ;
int iovix = 0 ;
int pageix = 0 ;
int pageoffset = 0 ;
size_t prev_ix = 0 ;
size_t next_ix ;
int cipher_active , digest_active , csum_active ;
int end_digest , end_csum ;
int digest_done = 0 ;
int cipher_done = 0 ;
int csum_done = 0 ;
DEBUG ( printk ( " cryptocop_ioctl_process \n " ) ) ;
if ( ! access_ok ( VERIFY_WRITE , crp_oper , sizeof ( struct strcop_crypto_op ) ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: !access_ok crp_oper! \n " ) ) ;
return - EFAULT ;
}
if ( copy_from_user ( & oper , crp_oper , sizeof ( struct strcop_crypto_op ) ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: copy_from_user \n " ) ) ;
return - EFAULT ;
}
DEBUG ( print_strcop_crypto_op ( & oper ) ) ;
while ( dev & & dev - > sid ! = oper . ses_id ) dev = dev - > next ;
if ( ! dev ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: session %lld not found \n " , oper . ses_id ) ) ;
return - EINVAL ;
}
/* Check buffers. */
if ( ( ( oper . indata + oper . inlen ) < oper . indata ) | | ( ( oper . cipher_outdata + oper . cipher_outlen ) < oper . cipher_outdata ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: user buffers wrapped around, bad user! \n " ) ) ;
return - EINVAL ;
}
if ( ! access_ok ( VERIFY_WRITE , oper . cipher_outdata , oper . cipher_outlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: !access_ok out data! \n " ) ) ;
return - EFAULT ;
}
if ( ! access_ok ( VERIFY_READ , oper . indata , oper . inlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: !access_ok in data! \n " ) ) ;
return - EFAULT ;
}
cop = kmalloc ( sizeof ( struct cryptocop_operation ) , GFP_KERNEL ) ;
if ( ! cop ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc \n " ) ) ;
return - ENOMEM ;
}
jc = kmalloc ( sizeof ( struct ioctl_job_cb_ctx ) , GFP_KERNEL ) ;
if ( ! jc ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc \n " ) ) ;
err = - ENOMEM ;
goto error_cleanup ;
}
jc - > processed = 0 ;
cop - > cb_data = jc ;
cop - > cb = ioctl_process_job_callback ;
cop - > operation_status = 0 ;
cop - > use_dmalists = 0 ;
cop - > in_interrupt = 0 ;
cop - > fast_callback = 0 ;
cop - > tfrm_op . tfrm_cfg = NULL ;
cop - > tfrm_op . desc = NULL ;
cop - > tfrm_op . indata = NULL ;
cop - > tfrm_op . incount = 0 ;
cop - > tfrm_op . inlen = 0 ;
cop - > tfrm_op . outdata = NULL ;
cop - > tfrm_op . outcount = 0 ;
cop - > tfrm_op . outlen = 0 ;
sess = get_session ( oper . ses_id ) ;
if ( ! sess ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: bad session id. \n " ) ) ;
kfree ( cop ) ;
kfree ( jc ) ;
return - EINVAL ;
}
if ( oper . do_cipher ) {
unsigned int cipher_outlen = 0 ;
struct cryptocop_transform_ctx * tc = get_transform_ctx ( sess , CRYPTOCOP_IOCTL_CIPHER_TID ) ;
if ( ! tc ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: no cipher transform in session. \n " ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
ciph_tcfg . tid = CRYPTOCOP_IOCTL_CIPHER_TID ;
ciph_tcfg . inject_ix = 0 ;
ciph_tcfg . flags = 0 ;
if ( ( oper . cipher_start < 0 ) | | ( oper . cipher_len < = 0 ) | | ( oper . cipher_start > oper . inlen ) | | ( ( oper . cipher_start + oper . cipher_len ) > oper . inlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: bad cipher length \n " ) ) ;
kfree ( cop ) ;
kfree ( jc ) ;
return - EINVAL ;
}
cblocklen = tc - > init . alg = = cryptocop_alg_aes ? AES_BLOCK_LENGTH : DES_BLOCK_LENGTH ;
if ( oper . cipher_len % cblocklen ) {
kfree ( cop ) ;
kfree ( jc ) ;
DEBUG_API ( printk ( " cryptocop_ioctl_process: cipher inlength not multiple of block length. \n " ) ) ;
return - EINVAL ;
}
cipher_outlen = oper . cipher_len ;
if ( tc - > init . cipher_mode = = cryptocop_cipher_mode_cbc ) {
if ( oper . cipher_explicit ) {
ciph_tcfg . flags | = CRYPTOCOP_EXPLICIT_IV ;
memcpy ( ciph_tcfg . iv , oper . cipher_iv , cblocklen ) ;
} else {
cipher_outlen = oper . cipher_len - cblocklen ;
}
} else {
if ( oper . cipher_explicit ) {
kfree ( cop ) ;
kfree ( jc ) ;
DEBUG_API ( printk ( " cryptocop_ioctl_process: explicit_iv when not CBC mode \n " ) ) ;
return - EINVAL ;
}
}
if ( oper . cipher_outlen ! = cipher_outlen ) {
kfree ( cop ) ;
kfree ( jc ) ;
DEBUG_API ( printk ( " cryptocop_ioctl_process: cipher_outlen incorrect, should be %d not %d. \n " , cipher_outlen , oper . cipher_outlen ) ) ;
return - EINVAL ;
}
if ( oper . decrypt ) {
ciph_tcfg . flags | = CRYPTOCOP_DECRYPT ;
} else {
ciph_tcfg . flags | = CRYPTOCOP_ENCRYPT ;
}
ciph_tcfg . next = cop - > tfrm_op . tfrm_cfg ;
cop - > tfrm_op . tfrm_cfg = & ciph_tcfg ;
}
if ( oper . do_digest ) {
struct cryptocop_transform_ctx * tc = get_transform_ctx ( sess , CRYPTOCOP_IOCTL_DIGEST_TID ) ;
if ( ! tc ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: no digest transform in session. \n " ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
digest_length = tc - > init . alg = = cryptocop_alg_md5 ? 16 : 20 ;
digest_result = kmalloc ( digest_length , GFP_KERNEL ) ;
if ( ! digest_result ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc digest_result \n " ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
DEBUG ( memset ( digest_result , 0xff , digest_length ) ) ;
digest_tcfg . tid = CRYPTOCOP_IOCTL_DIGEST_TID ;
digest_tcfg . inject_ix = 0 ;
ciph_tcfg . inject_ix + = digest_length ;
if ( ( oper . digest_start < 0 ) | | ( oper . digest_len < = 0 ) | | ( oper . digest_start > oper . inlen ) | | ( ( oper . digest_start + oper . digest_len ) > oper . inlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: bad digest length \n " ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
digest_tcfg . next = cop - > tfrm_op . tfrm_cfg ;
cop - > tfrm_op . tfrm_cfg = & digest_tcfg ;
}
if ( oper . do_csum ) {
csum_tcfg . tid = CRYPTOCOP_IOCTL_CSUM_TID ;
csum_tcfg . inject_ix = digest_length ;
ciph_tcfg . inject_ix + = 2 ;
if ( ( oper . csum_start < 0 ) | | ( oper . csum_len < = 0 ) | | ( oper . csum_start > oper . inlen ) | | ( ( oper . csum_start + oper . csum_len ) > oper . inlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: bad csum length \n " ) ) ;
kfree ( cop ) ;
kfree ( jc ) ;
return - EINVAL ;
}
csum_tcfg . next = cop - > tfrm_op . tfrm_cfg ;
cop - > tfrm_op . tfrm_cfg = & csum_tcfg ;
}
prev_ix = first_cfg_change_ix ( & oper ) ;
if ( prev_ix > oper . inlen ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: length mismatch \n " ) ) ;
nooutpages = noinpages = 0 ;
err = - EINVAL ;
goto error_cleanup ;
}
DEBUG ( printk ( " cryptocop_ioctl_process: inlen=%d, cipher_outlen=%d \n " , oper . inlen , oper . cipher_outlen ) ) ;
/* Map user pages for in and out data of the operation. */
noinpages = ( ( ( unsigned long int ) ( oper . indata + prev_ix ) & ~ PAGE_MASK ) + oper . inlen - 1 - prev_ix + ~ PAGE_MASK ) > > PAGE_SHIFT ;
DEBUG ( printk ( " cryptocop_ioctl_process: noinpages=%d \n " , noinpages ) ) ;
inpages = kmalloc ( noinpages * sizeof ( struct page * ) , GFP_KERNEL ) ;
if ( ! inpages ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc inpages \n " ) ) ;
nooutpages = noinpages = 0 ;
err = - ENOMEM ;
goto error_cleanup ;
}
if ( oper . do_cipher ) {
nooutpages = ( ( ( unsigned long int ) oper . cipher_outdata & ~ PAGE_MASK ) + oper . cipher_outlen - 1 + ~ PAGE_MASK ) > > PAGE_SHIFT ;
DEBUG ( printk ( " cryptocop_ioctl_process: nooutpages=%d \n " , nooutpages ) ) ;
outpages = kmalloc ( nooutpages * sizeof ( struct page * ) , GFP_KERNEL ) ;
if ( ! outpages ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc outpages \n " ) ) ;
nooutpages = noinpages = 0 ;
err = - ENOMEM ;
goto error_cleanup ;
}
}
/* Acquire the mm page semaphore. */
down_read ( & current - > mm - > mmap_sem ) ;
err = get_user_pages ( current ,
current - > mm ,
( unsigned long int ) ( oper . indata + prev_ix ) ,
noinpages ,
0 , /* read access only for in data */
0 , /* no force */
inpages ,
NULL ) ;
if ( err < 0 ) {
up_read ( & current - > mm - > mmap_sem ) ;
nooutpages = noinpages = 0 ;
DEBUG_API ( printk ( " cryptocop_ioctl_process: get_user_pages indata \n " ) ) ;
goto error_cleanup ;
}
noinpages = err ;
if ( oper . do_cipher ) {
err = get_user_pages ( current ,
current - > mm ,
( unsigned long int ) oper . cipher_outdata ,
nooutpages ,
1 , /* write access for out data */
0 , /* no force */
outpages ,
NULL ) ;
up_read ( & current - > mm - > mmap_sem ) ;
if ( err < 0 ) {
nooutpages = 0 ;
DEBUG_API ( printk ( " cryptocop_ioctl_process: get_user_pages outdata \n " ) ) ;
goto error_cleanup ;
}
nooutpages = err ;
} else {
up_read ( & current - > mm - > mmap_sem ) ;
}
/* Add 6 to nooutpages to make room for possibly inserted buffers for storing digest and
* csum output and splits when units are ( dis - ) connected . */
cop - > tfrm_op . indata = kmalloc ( ( noinpages ) * sizeof ( struct iovec ) , GFP_KERNEL ) ;
cop - > tfrm_op . outdata = kmalloc ( ( 6 + nooutpages ) * sizeof ( struct iovec ) , GFP_KERNEL ) ;
if ( ! cop - > tfrm_op . indata | | ! cop - > tfrm_op . outdata ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: kmalloc iovecs \n " ) ) ;
err = - ENOMEM ;
goto error_cleanup ;
}
cop - > tfrm_op . inlen = oper . inlen - prev_ix ;
cop - > tfrm_op . outlen = 0 ;
if ( oper . do_cipher ) cop - > tfrm_op . outlen + = oper . cipher_outlen ;
if ( oper . do_digest ) cop - > tfrm_op . outlen + = digest_length ;
if ( oper . do_csum ) cop - > tfrm_op . outlen + = 2 ;
/* Setup the in iovecs. */
cop - > tfrm_op . incount = noinpages ;
if ( noinpages > 1 ) {
size_t tmplen = cop - > tfrm_op . inlen ;
cop - > tfrm_op . indata [ 0 ] . iov_len = PAGE_SIZE - ( ( unsigned long int ) ( oper . indata + prev_ix ) & ~ PAGE_MASK ) ;
cop - > tfrm_op . indata [ 0 ] . iov_base = ( unsigned char * ) page_address ( inpages [ 0 ] ) + ( ( unsigned long int ) ( oper . indata + prev_ix ) & ~ PAGE_MASK ) ;
tmplen - = cop - > tfrm_op . indata [ 0 ] . iov_len ;
for ( i = 1 ; i < noinpages ; i + + ) {
cop - > tfrm_op . indata [ i ] . iov_len = tmplen < PAGE_SIZE ? tmplen : PAGE_SIZE ;
cop - > tfrm_op . indata [ i ] . iov_base = ( unsigned char * ) page_address ( inpages [ i ] ) ;
tmplen - = PAGE_SIZE ;
}
} else {
cop - > tfrm_op . indata [ 0 ] . iov_len = oper . inlen - prev_ix ;
cop - > tfrm_op . indata [ 0 ] . iov_base = ( unsigned char * ) page_address ( inpages [ 0 ] ) + ( ( unsigned long int ) ( oper . indata + prev_ix ) & ~ PAGE_MASK ) ;
}
iovlen = nooutpages + 6 ;
pageoffset = oper . do_cipher ? ( ( unsigned long int ) oper . cipher_outdata & ~ PAGE_MASK ) : 0 ;
next_ix = next_cfg_change_ix ( & oper , prev_ix ) ;
if ( prev_ix = = next_ix ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: length configuration broken. \n " ) ) ;
err = - EINVAL ; /* This should be impossible barring bugs. */
goto error_cleanup ;
}
while ( prev_ix ! = next_ix ) {
end_digest = end_csum = cipher_active = digest_active = csum_active = 0 ;
descs [ desc_ix ] . cfg = NULL ;
descs [ desc_ix ] . length = next_ix - prev_ix ;
if ( oper . do_cipher & & ( oper . cipher_start < next_ix ) & & ( prev_ix < ( oper . cipher_start + oper . cipher_len ) ) ) {
dcfgs [ dcfg_ix ] . tid = CRYPTOCOP_IOCTL_CIPHER_TID ;
dcfgs [ dcfg_ix ] . src = cryptocop_source_dma ;
cipher_active = 1 ;
if ( next_ix = = ( oper . cipher_start + oper . cipher_len ) ) {
cipher_done = 1 ;
dcfgs [ dcfg_ix ] . last = 1 ;
} else {
dcfgs [ dcfg_ix ] . last = 0 ;
}
dcfgs [ dcfg_ix ] . next = descs [ desc_ix ] . cfg ;
descs [ desc_ix ] . cfg = & dcfgs [ dcfg_ix ] ;
+ + dcfg_ix ;
}
if ( oper . do_digest & & ( oper . digest_start < next_ix ) & & ( prev_ix < ( oper . digest_start + oper . digest_len ) ) ) {
digest_active = 1 ;
dcfgs [ dcfg_ix ] . tid = CRYPTOCOP_IOCTL_DIGEST_TID ;
dcfgs [ dcfg_ix ] . src = cryptocop_source_dma ;
if ( next_ix = = ( oper . digest_start + oper . digest_len ) ) {
assert ( ! digest_done ) ;
digest_done = 1 ;
dcfgs [ dcfg_ix ] . last = 1 ;
} else {
dcfgs [ dcfg_ix ] . last = 0 ;
}
dcfgs [ dcfg_ix ] . next = descs [ desc_ix ] . cfg ;
descs [ desc_ix ] . cfg = & dcfgs [ dcfg_ix ] ;
+ + dcfg_ix ;
}
if ( oper . do_csum & & ( oper . csum_start < next_ix ) & & ( prev_ix < ( oper . csum_start + oper . csum_len ) ) ) {
csum_active = 1 ;
dcfgs [ dcfg_ix ] . tid = CRYPTOCOP_IOCTL_CSUM_TID ;
dcfgs [ dcfg_ix ] . src = cryptocop_source_dma ;
if ( next_ix = = ( oper . csum_start + oper . csum_len ) ) {
csum_done = 1 ;
dcfgs [ dcfg_ix ] . last = 1 ;
} else {
dcfgs [ dcfg_ix ] . last = 0 ;
}
dcfgs [ dcfg_ix ] . next = descs [ desc_ix ] . cfg ;
descs [ desc_ix ] . cfg = & dcfgs [ dcfg_ix ] ;
+ + dcfg_ix ;
}
if ( ! descs [ desc_ix ] . cfg ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: data segment %d (%d to %d) had no active transforms \n " , desc_ix , prev_ix , next_ix ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
descs [ desc_ix ] . next = & ( descs [ desc_ix ] ) + 1 ;
+ + desc_ix ;
prev_ix = next_ix ;
next_ix = next_cfg_change_ix ( & oper , prev_ix ) ;
}
if ( desc_ix > 0 ) {
descs [ desc_ix - 1 ] . next = NULL ;
} else {
descs [ 0 ] . next = NULL ;
}
if ( oper . do_digest ) {
DEBUG ( printk ( " cryptocop_ioctl_process: mapping %d byte digest output to iovec %d \n " , digest_length , iovix ) ) ;
/* Add outdata iovec, length == <length of type of digest> */
cop - > tfrm_op . outdata [ iovix ] . iov_base = digest_result ;
cop - > tfrm_op . outdata [ iovix ] . iov_len = digest_length ;
+ + iovix ;
}
if ( oper . do_csum ) {
/* Add outdata iovec, length == 2, the length of csum. */
DEBUG ( printk ( " cryptocop_ioctl_process: mapping 2 byte csum output to iovec %d \n " , iovix ) ) ;
/* Add outdata iovec, length == <length of type of digest> */
cop - > tfrm_op . outdata [ iovix ] . iov_base = csum_result ;
cop - > tfrm_op . outdata [ iovix ] . iov_len = 2 ;
+ + iovix ;
}
if ( oper . do_cipher ) {
if ( ! map_pages_to_iovec ( cop - > tfrm_op . outdata , iovlen , & iovix , outpages , nooutpages , & pageix , & pageoffset , oper . cipher_outlen ) ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: failed to map pages to iovec. \n " ) ) ;
err = - ENOSYS ; /* This should be impossible barring bugs. */
goto error_cleanup ;
}
}
DEBUG ( printk ( " cryptocop_ioctl_process: setting cop->tfrm_op.outcount %d \n " , iovix ) ) ;
cop - > tfrm_op . outcount = iovix ;
assert ( iovix < = ( nooutpages + 6 ) ) ;
cop - > sid = oper . ses_id ;
cop - > tfrm_op . desc = & descs [ 0 ] ;
DEBUG ( printk ( " cryptocop_ioctl_process: inserting job, cb_data=0x%p \n " , cop - > cb_data ) ) ;
if ( ( err = cryptocop_job_queue_insert_user_job ( cop ) ) ! = 0 ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: insert job %d \n " , err ) ) ;
err = - EINVAL ;
goto error_cleanup ;
}
DEBUG ( printk ( " cryptocop_ioctl_process: begin wait for result \n " ) ) ;
wait_event ( cryptocop_ioc_process_wq , ( jc - > processed ! = 0 ) ) ;
DEBUG ( printk ( " cryptocop_ioctl_process: end wait for result \n " ) ) ;
if ( ! jc - > processed ) {
printk ( KERN_WARNING " cryptocop_ioctl_process: job not processed at completion \n " ) ;
err = - EIO ;
goto error_cleanup ;
}
/* Job process done. Cipher output should already be correct in job so no post processing of outdata. */
DEBUG ( printk ( " cryptocop_ioctl_process: operation_status = %d \n " , cop - > operation_status ) ) ;
if ( cop - > operation_status = = 0 ) {
if ( oper . do_digest ) {
DEBUG ( printk ( " cryptocop_ioctl_process: copy %d bytes digest to user \n " , digest_length ) ) ;
err = copy_to_user ( ( unsigned char * ) crp_oper + offsetof ( struct strcop_crypto_op , digest ) , digest_result , digest_length ) ;
if ( 0 ! = err ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: copy_to_user, digest length %d, err %d \n " , digest_length , err ) ) ;
err = - EFAULT ;
goto error_cleanup ;
}
}
if ( oper . do_csum ) {
DEBUG ( printk ( " cryptocop_ioctl_process: copy 2 bytes checksum to user \n " ) ) ;
err = copy_to_user ( ( unsigned char * ) crp_oper + offsetof ( struct strcop_crypto_op , csum ) , csum_result , 2 ) ;
if ( 0 ! = err ) {
DEBUG_API ( printk ( " cryptocop_ioctl_process: copy_to_user, csum, err %d \n " , err ) ) ;
err = - EFAULT ;
goto error_cleanup ;
}
}
err = 0 ;
} else {
DEBUG ( printk ( " cryptocop_ioctl_process: returning err = operation_status = %d \n " , cop - > operation_status ) ) ;
err = cop - > operation_status ;
}
error_cleanup :
/* Release page caches. */
for ( i = 0 ; i < noinpages ; i + + ) {
put_page ( inpages [ i ] ) ;
}
for ( i = 0 ; i < nooutpages ; i + + ) {
int spdl_err ;
/* Mark output pages dirty. */
spdl_err = set_page_dirty_lock ( outpages [ i ] ) ;
2006-03-24 19:18:11 +08:00
DEBUG ( if ( spdl_err < 0 ) printk ( " cryptocop_ioctl_process: set_page_dirty_lock returned %d \n " , spdl_err ) ) ;
2005-07-28 02:44:44 +08:00
}
for ( i = 0 ; i < nooutpages ; i + + ) {
put_page ( outpages [ i ] ) ;
}
2005-11-07 17:01:35 +08:00
kfree ( digest_result ) ;
kfree ( inpages ) ;
kfree ( outpages ) ;
2005-07-28 02:44:44 +08:00
if ( cop ) {
2005-11-07 17:01:35 +08:00
kfree ( cop - > tfrm_op . indata ) ;
kfree ( cop - > tfrm_op . outdata ) ;
2005-07-28 02:44:44 +08:00
kfree ( cop ) ;
}
2005-11-07 17:01:35 +08:00
kfree ( jc ) ;
2005-07-28 02:44:44 +08:00
DEBUG ( print_lock_status ( ) ) ;
return err ;
}
static int cryptocop_ioctl_create_session ( struct inode * inode , struct file * filp , unsigned int cmd , unsigned long arg )
{
cryptocop_session_id sid ;
int err ;
struct cryptocop_private * dev ;
struct strcop_session_op * sess_op = ( struct strcop_session_op * ) arg ;
struct strcop_session_op sop ;
struct cryptocop_transform_init * tis = NULL ;
struct cryptocop_transform_init ti_cipher = { 0 } ;
struct cryptocop_transform_init ti_digest = { 0 } ;
struct cryptocop_transform_init ti_csum = { 0 } ;
if ( ! access_ok ( VERIFY_WRITE , sess_op , sizeof ( struct strcop_session_op ) ) )
return - EFAULT ;
err = copy_from_user ( & sop , sess_op , sizeof ( struct strcop_session_op ) ) ;
if ( err ) return - EFAULT ;
if ( sop . cipher ! = cryptocop_cipher_none ) {
if ( ! access_ok ( VERIFY_READ , sop . key , sop . keylen ) ) return - EFAULT ;
}
DEBUG ( printk ( " cryptocop_ioctl_create_session, sess_op: \n " ) ) ;
DEBUG ( printk ( " \t cipher:%d \n "
" \t cipher_mode:%d \n "
" \t digest:%d \n "
" \t csum:%d \n " ,
( int ) sop . cipher ,
( int ) sop . cmode ,
( int ) sop . digest ,
( int ) sop . csum ) ) ;
if ( sop . cipher ! = cryptocop_cipher_none ) {
/* Init the cipher. */
switch ( sop . cipher ) {
case cryptocop_cipher_des :
ti_cipher . alg = cryptocop_alg_des ;
break ;
case cryptocop_cipher_3des :
ti_cipher . alg = cryptocop_alg_3des ;
break ;
case cryptocop_cipher_aes :
ti_cipher . alg = cryptocop_alg_aes ;
break ;
default :
DEBUG_API ( printk ( " create session, bad cipher algorithm %d \n " , sop . cipher ) ) ;
return - EINVAL ;
} ;
DEBUG ( printk ( " setting cipher transform %d \n " , ti_cipher . alg ) ) ;
copy_from_user ( ti_cipher . key , sop . key , sop . keylen / 8 ) ;
ti_cipher . keylen = sop . keylen ;
switch ( sop . cmode ) {
case cryptocop_cipher_mode_cbc :
case cryptocop_cipher_mode_ecb :
ti_cipher . cipher_mode = sop . cmode ;
break ;
default :
DEBUG_API ( printk ( " create session, bad cipher mode %d \n " , sop . cmode ) ) ;
return - EINVAL ;
}
DEBUG ( printk ( " cryptocop_ioctl_create_session: setting CBC mode %d \n " , ti_cipher . cipher_mode ) ) ;
switch ( sop . des3_mode ) {
case cryptocop_3des_eee :
case cryptocop_3des_eed :
case cryptocop_3des_ede :
case cryptocop_3des_edd :
case cryptocop_3des_dee :
case cryptocop_3des_ded :
case cryptocop_3des_dde :
case cryptocop_3des_ddd :
ti_cipher . tdes_mode = sop . des3_mode ;
break ;
default :
DEBUG_API ( printk ( " create session, bad 3DES mode %d \n " , sop . des3_mode ) ) ;
return - EINVAL ;
}
ti_cipher . tid = CRYPTOCOP_IOCTL_CIPHER_TID ;
ti_cipher . next = tis ;
tis = & ti_cipher ;
} /* if (sop.cipher != cryptocop_cipher_none) */
if ( sop . digest ! = cryptocop_digest_none ) {
DEBUG ( printk ( " setting digest transform \n " ) ) ;
switch ( sop . digest ) {
case cryptocop_digest_md5 :
ti_digest . alg = cryptocop_alg_md5 ;
break ;
case cryptocop_digest_sha1 :
ti_digest . alg = cryptocop_alg_sha1 ;
break ;
default :
DEBUG_API ( printk ( " create session, bad digest algorithm %d \n " , sop . digest ) ) ;
return - EINVAL ;
}
ti_digest . tid = CRYPTOCOP_IOCTL_DIGEST_TID ;
ti_digest . next = tis ;
tis = & ti_digest ;
} /* if (sop.digest != cryptocop_digest_none) */
if ( sop . csum ! = cryptocop_csum_none ) {
DEBUG ( printk ( " setting csum transform \n " ) ) ;
switch ( sop . csum ) {
case cryptocop_csum_le :
case cryptocop_csum_be :
ti_csum . csum_mode = sop . csum ;
break ;
default :
DEBUG_API ( printk ( " create session, bad checksum algorithm %d \n " , sop . csum ) ) ;
return - EINVAL ;
}
ti_csum . alg = cryptocop_alg_csum ;
ti_csum . tid = CRYPTOCOP_IOCTL_CSUM_TID ;
ti_csum . next = tis ;
tis = & ti_csum ;
} /* (sop.csum != cryptocop_csum_none) */
dev = kmalloc ( sizeof ( struct cryptocop_private ) , GFP_KERNEL ) ;
if ( ! dev ) {
DEBUG_API ( printk ( " create session, alloc dev \n " ) ) ;
return - ENOMEM ;
}
err = cryptocop_new_session ( & sid , tis , GFP_KERNEL ) ;
DEBUG ( { if ( err ) printk ( " create session, cryptocop_new_session %d \n " , err ) ; } ) ;
if ( err ) {
kfree ( dev ) ;
return err ;
}
sess_op - > ses_id = sid ;
dev - > sid = sid ;
dev - > next = filp - > private_data ;
filp - > private_data = dev ;
return 0 ;
}
static int cryptocop_ioctl ( struct inode * inode , struct file * filp , unsigned int cmd , unsigned long arg )
{
int err = 0 ;
if ( _IOC_TYPE ( cmd ) ! = ETRAXCRYPTOCOP_IOCTYPE ) {
DEBUG_API ( printk ( " cryptocop_ioctl: wrong type \n " ) ) ;
return - ENOTTY ;
}
if ( _IOC_NR ( cmd ) > CRYPTOCOP_IO_MAXNR ) {
return - ENOTTY ;
}
/* Access check of the argument. Some commands, e.g. create session and process op,
needs additional checks . Those are handled in the command handling functions . */
if ( _IOC_DIR ( cmd ) & _IOC_READ )
err = ! access_ok ( VERIFY_WRITE , ( void * ) arg , _IOC_SIZE ( cmd ) ) ;
else if ( _IOC_DIR ( cmd ) & _IOC_WRITE )
err = ! access_ok ( VERIFY_READ , ( void * ) arg , _IOC_SIZE ( cmd ) ) ;
if ( err ) return - EFAULT ;
switch ( cmd ) {
case CRYPTOCOP_IO_CREATE_SESSION :
return cryptocop_ioctl_create_session ( inode , filp , cmd , arg ) ;
case CRYPTOCOP_IO_CLOSE_SESSION :
return cryptocop_ioctl_close_session ( inode , filp , cmd , arg ) ;
case CRYPTOCOP_IO_PROCESS_OP :
return cryptocop_ioctl_process ( inode , filp , cmd , arg ) ;
default :
DEBUG_API ( printk ( " cryptocop_ioctl: unknown command \n " ) ) ;
return - ENOTTY ;
}
return 0 ;
}
# ifdef LDEBUG
static void print_dma_descriptors ( struct cryptocop_int_operation * iop )
{
struct cryptocop_dma_desc * cdesc_out = iop - > cdesc_out ;
struct cryptocop_dma_desc * cdesc_in = iop - > cdesc_in ;
int i ;
printk ( " print_dma_descriptors start \n " ) ;
printk ( " iop: \n " ) ;
printk ( " \t sid: 0x%lld \n " , iop - > sid ) ;
printk ( " \t cdesc_out: 0x%p \n " , iop - > cdesc_out ) ;
printk ( " \t cdesc_in: 0x%p \n " , iop - > cdesc_in ) ;
printk ( " \t ddesc_out: 0x%p \n " , iop - > ddesc_out ) ;
printk ( " \t ddesc_in: 0x%p \n " , iop - > ddesc_in ) ;
printk ( " \n iop->ctx_out: 0x%p phys: 0x%p \n " , & iop - > ctx_out , ( char * ) virt_to_phys ( & iop - > ctx_out ) ) ;
printk ( " \t next: 0x%p \n "
" \t saved_data: 0x%p \n "
" \t saved_data_buf: 0x%p \n " ,
iop - > ctx_out . next ,
iop - > ctx_out . saved_data ,
iop - > ctx_out . saved_data_buf ) ;
printk ( " \n iop->ctx_in: 0x%p phys: 0x%p \n " , & iop - > ctx_in , ( char * ) virt_to_phys ( & iop - > ctx_in ) ) ;
printk ( " \t next: 0x%p \n "
" \t saved_data: 0x%p \n "
" \t saved_data_buf: 0x%p \n " ,
iop - > ctx_in . next ,
iop - > ctx_in . saved_data ,
iop - > ctx_in . saved_data_buf ) ;
i = 0 ;
while ( cdesc_out ) {
dma_descr_data * td ;
printk ( " cdesc_out %d, desc=0x%p \n " , i , cdesc_out - > dma_descr ) ;
printk ( " \n \t virt_to_phys(desc): 0x%p \n " , ( char * ) virt_to_phys ( cdesc_out - > dma_descr ) ) ;
td = cdesc_out - > dma_descr ;
printk ( " \n \t buf: 0x%p \n "
" \t after: 0x%p \n "
" \t md: 0x%04x \n "
" \t next: 0x%p \n " ,
td - > buf ,
td - > after ,
td - > md ,
td - > next ) ;
printk ( " flags: \n "
" \t wait: \t %d \n "
" \t eol: \t %d \n "
" \t outeop: \t %d \n "
" \t ineop: \t %d \n "
" \t intr: \t %d \n " ,
td - > wait ,
td - > eol ,
td - > out_eop ,
td - > in_eop ,
td - > intr ) ;
cdesc_out = cdesc_out - > next ;
i + + ;
}
i = 0 ;
while ( cdesc_in ) {
dma_descr_data * td ;
printk ( " cdesc_in %d, desc=0x%p \n " , i , cdesc_in - > dma_descr ) ;
printk ( " \n \t virt_to_phys(desc): 0x%p \n " , ( char * ) virt_to_phys ( cdesc_in - > dma_descr ) ) ;
td = cdesc_in - > dma_descr ;
printk ( " \n \t buf: 0x%p \n "
" \t after: 0x%p \n "
" \t md: 0x%04x \n "
" \t next: 0x%p \n " ,
td - > buf ,
td - > after ,
td - > md ,
td - > next ) ;
printk ( " flags: \n "
" \t wait: \t %d \n "
" \t eol: \t %d \n "
" \t outeop: \t %d \n "
" \t ineop: \t %d \n "
" \t intr: \t %d \n " ,
td - > wait ,
td - > eol ,
td - > out_eop ,
td - > in_eop ,
td - > intr ) ;
cdesc_in = cdesc_in - > next ;
i + + ;
}
printk ( " print_dma_descriptors end \n " ) ;
}
static void print_strcop_crypto_op ( struct strcop_crypto_op * cop )
{
printk ( " print_strcop_crypto_op, 0x%p \n " , cop ) ;
/* Indata. */
printk ( " indata=0x%p \n "
" inlen=%d \n "
" do_cipher=%d \n "
" decrypt=%d \n "
" cipher_explicit=%d \n "
" cipher_start=%d \n "
" cipher_len=%d \n "
" outdata=0x%p \n "
" outlen=%d \n " ,
cop - > indata ,
cop - > inlen ,
cop - > do_cipher ,
cop - > decrypt ,
cop - > cipher_explicit ,
cop - > cipher_start ,
cop - > cipher_len ,
cop - > cipher_outdata ,
cop - > cipher_outlen ) ;
printk ( " do_digest=%d \n "
" digest_start=%d \n "
" digest_len=%d \n " ,
cop - > do_digest ,
cop - > digest_start ,
cop - > digest_len ) ;
printk ( " do_csum=%d \n "
" csum_start=%d \n "
" csum_len=%d \n " ,
cop - > do_csum ,
cop - > csum_start ,
cop - > csum_len ) ;
}
static void print_cryptocop_operation ( struct cryptocop_operation * cop )
{
struct cryptocop_desc * d ;
struct cryptocop_tfrm_cfg * tc ;
struct cryptocop_desc_cfg * dc ;
int i ;
printk ( " print_cryptocop_operation, cop=0x%p \n \n " , cop ) ;
printk ( " sid: %lld \n " , cop - > sid ) ;
printk ( " operation_status=%d \n "
" use_dmalists=%d \n "
" in_interrupt=%d \n "
" fast_callback=%d \n " ,
cop - > operation_status ,
cop - > use_dmalists ,
cop - > in_interrupt ,
cop - > fast_callback ) ;
if ( cop - > use_dmalists ) {
print_user_dma_lists ( & cop - > list_op ) ;
} else {
printk ( " cop->tfrm_op \n "
" tfrm_cfg=0x%p \n "
" desc=0x%p \n "
" indata=0x%p \n "
" incount=%d \n "
" inlen=%d \n "
" outdata=0x%p \n "
" outcount=%d \n "
" outlen=%d \n \n " ,
cop - > tfrm_op . tfrm_cfg ,
cop - > tfrm_op . desc ,
cop - > tfrm_op . indata ,
cop - > tfrm_op . incount ,
cop - > tfrm_op . inlen ,
cop - > tfrm_op . outdata ,
cop - > tfrm_op . outcount ,
cop - > tfrm_op . outlen ) ;
tc = cop - > tfrm_op . tfrm_cfg ;
while ( tc ) {
printk ( " tfrm_cfg, 0x%p \n "
" tid=%d \n "
" flags=%d \n "
" inject_ix=%d \n "
" next=0x%p \n " ,
tc ,
tc - > tid ,
tc - > flags ,
tc - > inject_ix ,
tc - > next ) ;
tc = tc - > next ;
}
d = cop - > tfrm_op . desc ;
while ( d ) {
printk ( " \n ======================desc, 0x%p \n "
" length=%d \n "
" cfg=0x%p \n "
" next=0x%p \n " ,
d ,
d - > length ,
d - > cfg ,
d - > next ) ;
dc = d - > cfg ;
while ( dc ) {
printk ( " =========desc_cfg, 0x%p \n "
" tid=%d \n "
" src=%d \n "
" last=%d \n "
" next=0x%p \n " ,
dc ,
dc - > tid ,
dc - > src ,
dc - > last ,
dc - > next ) ;
dc = dc - > next ;
}
d = d - > next ;
}
printk ( " \n ====iniov \n " ) ;
for ( i = 0 ; i < cop - > tfrm_op . incount ; i + + ) {
printk ( " indata[%d] \n "
" base=0x%p \n "
" len=%d \n " ,
i ,
cop - > tfrm_op . indata [ i ] . iov_base ,
cop - > tfrm_op . indata [ i ] . iov_len ) ;
}
printk ( " \n ====outiov \n " ) ;
for ( i = 0 ; i < cop - > tfrm_op . outcount ; i + + ) {
printk ( " outdata[%d] \n "
" base=0x%p \n "
" len=%d \n " ,
i ,
cop - > tfrm_op . outdata [ i ] . iov_base ,
cop - > tfrm_op . outdata [ i ] . iov_len ) ;
}
}
printk ( " ------------end print_cryptocop_operation \n " ) ;
}
static void print_user_dma_lists ( struct cryptocop_dma_list_operation * dma_op )
{
dma_descr_data * dd ;
int i ;
printk ( " print_user_dma_lists, dma_op=0x%p \n " , dma_op ) ;
printk ( " out_data_buf = 0x%p, phys_to_virt(out_data_buf) = 0x%p \n " , dma_op - > out_data_buf , phys_to_virt ( ( unsigned long int ) dma_op - > out_data_buf ) ) ;
printk ( " in_data_buf = 0x%p, phys_to_virt(in_data_buf) = 0x%p \n " , dma_op - > in_data_buf , phys_to_virt ( ( unsigned long int ) dma_op - > in_data_buf ) ) ;
printk ( " ##############outlist \n " ) ;
dd = phys_to_virt ( ( unsigned long int ) dma_op - > outlist ) ;
i = 0 ;
while ( dd ! = NULL ) {
printk ( " #%d phys_to_virt(desc) 0x%p \n " , i , dd ) ;
printk ( " \n \t buf: 0x%p \n "
" \t after: 0x%p \n "
" \t md: 0x%04x \n "
" \t next: 0x%p \n " ,
dd - > buf ,
dd - > after ,
dd - > md ,
dd - > next ) ;
printk ( " flags: \n "
" \t wait: \t %d \n "
" \t eol: \t %d \n "
" \t outeop: \t %d \n "
" \t ineop: \t %d \n "
" \t intr: \t %d \n " ,
dd - > wait ,
dd - > eol ,
dd - > out_eop ,
dd - > in_eop ,
dd - > intr ) ;
if ( dd - > eol )
dd = NULL ;
else
dd = phys_to_virt ( ( unsigned long int ) dd - > next ) ;
+ + i ;
}
printk ( " ##############inlist \n " ) ;
dd = phys_to_virt ( ( unsigned long int ) dma_op - > inlist ) ;
i = 0 ;
while ( dd ! = NULL ) {
printk ( " #%d phys_to_virt(desc) 0x%p \n " , i , dd ) ;
printk ( " \n \t buf: 0x%p \n "
" \t after: 0x%p \n "
" \t md: 0x%04x \n "
" \t next: 0x%p \n " ,
dd - > buf ,
dd - > after ,
dd - > md ,
dd - > next ) ;
printk ( " flags: \n "
" \t wait: \t %d \n "
" \t eol: \t %d \n "
" \t outeop: \t %d \n "
" \t ineop: \t %d \n "
" \t intr: \t %d \n " ,
dd - > wait ,
dd - > eol ,
dd - > out_eop ,
dd - > in_eop ,
dd - > intr ) ;
if ( dd - > eol )
dd = NULL ;
else
dd = phys_to_virt ( ( unsigned long int ) dd - > next ) ;
+ + i ;
}
}
static void print_lock_status ( void )
{
printk ( " **********************print_lock_status \n " ) ;
printk ( " cryptocop_completed_jobs_lock %d \n " , spin_is_locked ( & cryptocop_completed_jobs_lock ) ) ;
printk ( " cryptocop_job_queue_lock %d \n " , spin_is_locked ( & cryptocop_job_queue_lock ) ) ;
printk ( " descr_pool_lock %d \n " , spin_is_locked ( & descr_pool_lock ) ) ;
printk ( " cryptocop_sessions_lock %d \n " , spin_is_locked ( cryptocop_sessions_lock ) ) ;
printk ( " running_job_lock %d \n " , spin_is_locked ( running_job_lock ) ) ;
printk ( " cryptocop_process_lock %d \n " , spin_is_locked ( cryptocop_process_lock ) ) ;
}
# endif /* LDEBUG */
static const char cryptocop_name [ ] = " ETRAX FS stream co-processor " ;
static int init_stream_coprocessor ( void )
{
int err ;
int i ;
static int initialized = 0 ;
if ( initialized )
return 0 ;
initialized = 1 ;
printk ( " ETRAX FS stream co-processor driver v0.01, (c) 2003 Axis Communications AB \n " ) ;
err = register_chrdev ( CRYPTOCOP_MAJOR , cryptocop_name , & cryptocop_fops ) ;
if ( err < 0 ) {
printk ( KERN_ERR " stream co-processor: could not get major number. \n " ) ;
return err ;
}
err = init_cryptocop ( ) ;
if ( err ) {
( void ) unregister_chrdev ( CRYPTOCOP_MAJOR , cryptocop_name ) ;
return err ;
}
err = cryptocop_job_queue_init ( ) ;
if ( err ) {
release_cryptocop ( ) ;
( void ) unregister_chrdev ( CRYPTOCOP_MAJOR , cryptocop_name ) ;
return err ;
}
/* Init the descriptor pool. */
for ( i = 0 ; i < CRYPTOCOP_DESCRIPTOR_POOL_SIZE - 1 ; i + + ) {
descr_pool [ i ] . from_pool = 1 ;
descr_pool [ i ] . next = & descr_pool [ i + 1 ] ;
}
descr_pool [ i ] . from_pool = 1 ;
descr_pool [ i ] . next = NULL ;
descr_pool_free_list = & descr_pool [ 0 ] ;
descr_pool_no_free = CRYPTOCOP_DESCRIPTOR_POOL_SIZE ;
spin_lock_init ( & cryptocop_completed_jobs_lock ) ;
spin_lock_init ( & cryptocop_job_queue_lock ) ;
spin_lock_init ( & descr_pool_lock ) ;
spin_lock_init ( & cryptocop_sessions_lock ) ;
spin_lock_init ( & running_job_lock ) ;
spin_lock_init ( & cryptocop_process_lock ) ;
cryptocop_sessions = NULL ;
next_sid = 1 ;
cryptocop_running_job = NULL ;
printk ( " stream co-processor: init done. \n " ) ;
return 0 ;
}
static void __exit exit_stream_coprocessor ( void )
{
release_cryptocop ( ) ;
cryptocop_job_queue_close ( ) ;
}
module_init ( init_stream_coprocessor ) ;
module_exit ( exit_stream_coprocessor ) ;