source: soft/giet_vm/giet_drivers/bdv_driver.c @ 309

Last change on this file since 309 was 297, checked in by alain, 11 years ago

Bug fix in both _tty_rx_isr() and _bdv_isr():
The ISR must do nothing it the status indicates that
there is no pending ISR.

File size: 14.1 KB
Line 
1///////////////////////////////////////////////////////////////////////////////////
2// File      : bdv_driver.c
3// Date      : 23/05/2013
4// Author    : alain greiner
5// Maintainer: cesar fuguet
6// Copyright (c) UPMC-LIP6
7///////////////////////////////////////////////////////////////////////////////////
8// The bdv_driver.c and bdv_driver.h files are part ot the GIET-VM kernel.
9// This driver supports the SocLib vci_block_device component, that is
10// a single channel, block oriented, external storage contrÃŽler.
11//
12// The _bdv_read() and _bdv_write() functions are always blocking.
13// They can be called in 3 modes:
14//
15// - In BOOT mode, these functions use a polling policy on the BDV STATUS
16//   register to detect transfer completion, as interrupts are not activated.
17//   This mode is used by the boot code to load the map.bin file into memory
18//   (before MMU activation), or to load the .elf files (after MMU activation).
19//
20// - In KERNEL mode, these functions use a descheduling strategy:
21//   The ISR executed when transfer completes should restart the calling task.
22//   There is no checking of user access right to the memory buffer.
23//   This mode must be used, for an "open" system call.
24//
25// - In USER mode, these functions use a descheduling strategy:
26//   The ISR executed when transfer completes should restart the calling task,
27//   The user access right to the memory buffer must be checked.
28//   This mode must be used for a "read/write" system call.
29//
30// As the BDV component can be used by several programs running in parallel,
31// the _bdv_lock variable guaranties exclusive access to the device.  The
32// _bdv_read() and _bdv_write() functions use atomic LL/SC to get the lock.
33//
34// Finally, the memory buffer must fulfill the following conditions:
35// - The buffer must be word aligned,
36// - The buffer must be mapped in user space for an user access,
37// - The buffer must be writable in case of (to_mem) access,
38// - The total number of physical pages occupied by the user buffer cannot
39//   be larger than 512 pages if the IOMMU is activated,
40// - All physical pages occupied by the user buffer must be contiguous
41//   if the IOMMU is not activated.
42// An error code is returned if these conditions are not verified.
43//
44// The "seg_ioc_base" must be defined in giet_vsegs.ld file.
45///////////////////////////////////////////////////////////////////////////////////
46// Implementation notes:
47//
48// 1. In order to share code, the two _bdv_read() and _bdv_write() functions
49//    call the same _bdv_access() function.
50//
51// 2. All accesses to BDV registers are done by the two
52//    _bdv_set_register() and _bdv_get_register() low-level functions,
53//    that are handling virtual / physical extended addressing.
54///////////////////////////////////////////////////////////////////////////////////
55
56#include <giet_config.h>
57#include <bdv_driver.h>
58#include <xcu_driver.h>
59#include <ioc_driver.h>
60#include <utils.h>
61#include <tty_driver.h>
62#include <ctx_handler.h>
63
64///////////////////////////////////////////////////////////////////////////////
65// BDV global variables
66///////////////////////////////////////////////////////////////////////////////
67
68#define in_unckdata __attribute__((section (".unckdata")))
69
70in_unckdata unsigned int          _bdv_lock = 0;
71in_unckdata volatile unsigned int _bdv_status = 0;
72in_unckdata volatile unsigned int _bdv_gtid;
73
74///////////////////////////////////////////////////////////////////////////////
75// This low_level function returns the value contained in register (index).
76///////////////////////////////////////////////////////////////////////////////
77unsigned int _bdv_get_register( unsigned int index )
78{
79    unsigned int* vaddr = (unsigned int*)&seg_ioc_base + index;
80    return _io_extended_read( vaddr );
81}
82
83///////////////////////////////////////////////////////////////////////////////
84// This low-level function set a new value in register (index).
85///////////////////////////////////////////////////////////////////////////////
86void _bdv_set_register( unsigned int index,
87                        unsigned int value ) 
88{
89    unsigned int* vaddr = (unsigned int*)&seg_ioc_base + index;
90    _io_extended_write( vaddr, value );
91}
92
93///////////////////////////////////////////////////////////////////////////////
94// This function transfer data between a memory buffer and the block device.
95// The buffer lentgth is (count*block_size) bytes.
96// Arguments are:
97// - to_mem     : from external storage to memory when non 0.
98// - mode       : BOOT / KERNEL / USER
99// - lba        : first block index on the external storage.
100// - buf_paddr  : physical base address of the memory buffer.
101// - count      : number of blocks to be transfered.
102// Returns 0 if success, > 0 if error.
103///////////////////////////////////////////////////////////////////////////////
104static unsigned int _bdv_access( unsigned int       to_mem,
105                                 unsigned int       mode,
106                                 unsigned int       lba,
107                                 unsigned long long buf_paddr,
108                                 unsigned int       count) 
109{
110
111#if GIET_DEBUG_BDV_DRIVER
112unsigned int procid  = _get_procid();
113unsigned int cxy     = procid / NB_PROCS_MAX;
114unsigned int lpid    = procid % NB_PROCS_MAX;
115unsigned int x       = cxy >> Y_WIDTH;
116unsigned int y       = cxy & ((1<<Y_WIDTH) - 1);
117
118_printf("\n[BDV DEBUG] Processor[%d,%d,%d] enters _bdv_access() at cycle %d\n"
119        " - mode    = %d\n"
120        " - paddr   = %l\n"
121        " - sectors = %x\n"
122        " - lba     = %x\n",
123        x, y, lpid, _get_proctime(), mode, buf_paddr, count, lba );
124#endif
125
126    unsigned int       error = 0;
127
128    // get the lock protecting BDV
129    _get_lock(&_bdv_lock);
130
131    // set device registers
132    _bdv_set_register( BLOCK_DEVICE_BUFFER    , (unsigned int)buf_paddr );
133    _bdv_set_register( BLOCK_DEVICE_BUFFER_EXT, (unsigned int)(buf_paddr>>32) );
134    _bdv_set_register( BLOCK_DEVICE_COUNT     , count );
135    _bdv_set_register( BLOCK_DEVICE_LBA       , lba );
136
137    // In BOOT mode, we launch transfer, and poll the BDV_STATUS
138    // register because IRQs are masked.
139    if ( mode == IOC_BOOT_MODE ) 
140    {
141        // Launch transfert
142        if (to_mem == 0) _bdv_set_register( BLOCK_DEVICE_OP, BLOCK_DEVICE_WRITE );
143        else             _bdv_set_register( BLOCK_DEVICE_OP, BLOCK_DEVICE_READ );
144
145        unsigned int status;
146        do
147        {
148            status = _bdv_get_register( BLOCK_DEVICE_STATUS );
149
150#if GIET_DEBUG_BDV_DRIVER
151_printf("\n[BDV DEBUG] _bdv_access() : ... waiting on BDV_STATUS register ...\n");
152#endif
153        }
154        while( (status != BLOCK_DEVICE_READ_SUCCESS)  &&
155               (status != BLOCK_DEVICE_READ_ERROR)    &&
156               (status != BLOCK_DEVICE_WRITE_SUCCESS) &&
157               (status != BLOCK_DEVICE_WRITE_ERROR)   );      // busy waiting
158
159        // analyse status
160        error = ( (status == BLOCK_DEVICE_READ_ERROR) ||
161                  (status == BLOCK_DEVICE_WRITE_ERROR) );
162
163        // release lock
164        _release_lock(&_bdv_lock);     
165    }
166    // in USER or KERNEL mode, we deschedule the task.
167    // When the task is rescheduled, we check the _bdv_status variable,
168    // and release the lock.
169    // We need a critical section, because we must reset the RUN bit
170        // before to launch the transfer, and we don't want to be descheduled
171        // between these two operations.
172    else
173    {
174        unsigned int save_sr;
175        unsigned int ltid = _get_current_task_id();
176        unsigned int gpid = _get_procid();
177
178        // activates BDV interrupts
179        _bdv_set_register( BLOCK_DEVICE_IRQ_ENABLE, 1 );
180
181        // set the _bdv_status variable
182        _bdv_status = BLOCK_DEVICE_BUSY;
183
184        // enters critical section
185        _it_disable( &save_sr ); 
186       
187        // set _bdv_gtid and reset runnable
188        _bdv_gtid = (gpid<<16) + ltid;
189        _set_task_slot( gpid, ltid, CTX_RUN_ID, 0 ); 
190       
191        // launch transfer
192        if (to_mem == 0) _bdv_set_register( BLOCK_DEVICE_OP, BLOCK_DEVICE_WRITE );
193        else             _bdv_set_register( BLOCK_DEVICE_OP, BLOCK_DEVICE_READ  );
194
195        // deschedule task
196        _ctx_switch();                     
197
198        // restore SR
199        _it_restore( &save_sr );
200
201        // analyse status
202        error = ( (_bdv_status == BLOCK_DEVICE_READ_ERROR) ||
203                  (_bdv_status == BLOCK_DEVICE_WRITE_ERROR) );
204
205        // reset _bdv_status and release lock
206        _bdv_status = BLOCK_DEVICE_IDLE; 
207        _release_lock(&_bdv_lock);     
208    }
209
210#if GIET_DEBUG_BDV_DRIVER
211_printf("\n[BDV DEBUG] Processor[%d,%d,%d] exit _bdv_access() at cycle %d\n",
212        x, y, lpid, _get_proctime() );
213#endif
214
215    return error;
216} // end _bdv_access()
217
218///////////////////////////////////////////////////////////////////////////////
219// This function cheks block size, and desactivates the interrupts.
220// Return 0 for success, > 0 if error
221///////////////////////////////////////////////////////////////////////////////
222unsigned int _bdv_init()
223{
224    if ( _bdv_get_register( BLOCK_DEVICE_BLOCK_SIZE ) != 512 )
225    {
226        _printf("\n[GIET ERROR] in _bdv_init() : block size must be 512 bytes\n");
227        return 1; 
228    }
229
230    _bdv_set_register( BLOCK_DEVICE_IRQ_ENABLE, 0 );
231    return 0;
232}
233
234///////////////////////////////////////////////////////////////////////////////
235// Transfer data from the block device to a memory buffer.
236// - mode     : BOOT / KERNEL / USER
237// - lba      : first block index on the block device
238// - buffer   : base address of the memory buffer (must be word aligned)
239// - count    : number of blocks to be transfered.
240// Returns 0 if success, > 0 if error.
241///////////////////////////////////////////////////////////////////////////////
242unsigned int _bdv_read( unsigned int       mode, 
243                        unsigned int       lba, 
244                        unsigned long long buffer, 
245                        unsigned int       count) 
246{
247    return _bdv_access( 1,        // read access
248                        mode, 
249                        lba,
250                        buffer,
251                        count );
252}
253
254///////////////////////////////////////////////////////////////////////////////
255// Transfer data from a memory buffer to the block device.
256// - mode     : BOOT / KERNEL / USER
257// - lba      : first block index on the block device
258// - buffer   : base address of the memory buffer (must be word aligned)
259// - count    : number of blocks to be transfered.
260// Returns 0 if success, > 0 if error.
261///////////////////////////////////////////////////////////////////////////////
262unsigned int _bdv_write( unsigned int       mode, 
263                         unsigned int       lba, 
264                         unsigned long long buffer, 
265                         unsigned int       count ) 
266{
267    return _bdv_access( 0,        // write access
268                        mode, 
269                        lba,
270                        buffer,
271                        count );
272}
273
274///////////////////////////////////////////////////////////////////////////////
275// Returns device status.
276///////////////////////////////////////////////////////////////////////////////
277unsigned int _bdv_get_status()
278{
279    return _bdv_get_register( BLOCK_DEVICE_STATUS );
280}
281
282///////////////////////////////////////////////////////////////////////////////
283// Returns block size.
284///////////////////////////////////////////////////////////////////////////////
285unsigned int _bdv_get_block_size()
286{
287    return _bdv_get_register( BLOCK_DEVICE_BLOCK_SIZE );
288}
289
290///////////////////////////////////////////////////////////////////////////////////
291// This ISR save the status, acknowledge the IRQ,
292// and activates the task waiting on IO transfer.
293// It can be an HWI or a SWI.
294//
295// TODO the _set_task_slot access should be replaced by an atomic LL/SC
296//      when the CTX_RUN bool will be replaced by a bit_vector.
297///////////////////////////////////////////////////////////////////////////////////
298void _bdv_isr( unsigned int irq_type,   // HWI / WTI
299               unsigned int irq_id,     // index returned by ICU
300               unsigned int channel )   // unused
301{
302    unsigned int procid     = _get_procid();
303    unsigned int cluster_xy = procid / NB_PROCS_MAX;
304    unsigned int lpid       = procid % NB_PROCS_MAX;
305
306    // get BDV status (and reset IRQ)
307    unsigned int status =  _bdv_get_register( BLOCK_DEVICE_STATUS ); 
308
309    // check status: does nothing if IDLE or BUSY
310    if ( (status == BLOCK_DEVICE_IDLE) ||
311         (status == BLOCK_DEVICE_BUSY) )   return;
312 
313    // reset WTI in XCU if WTI type
314    if ( irq_type == IRQ_TYPE_WTI ) 
315    {
316        unsigned int value;
317        _xcu_get_wti_value( cluster_xy, irq_id, &value );
318    }
319   
320    // save status in kernel buffer _bdv_status
321    _bdv_status = status; 
322
323    // identify task waiting on BDV
324    unsigned int rprocid    = _bdv_gtid>>16;
325    unsigned int ltid       = _bdv_gtid & 0xFFFF;
326    unsigned int remote_xy  = rprocid / NB_PROCS_MAX;
327
328    // re-activates sleeping task
329    _set_task_slot( rprocid,     // global processor index
330                    ltid,        // local task index on processor
331                    CTX_RUN_ID,  // CTX_RUN slot
332                    1 );         // running
333
334    // requires a context switch for remote processor running the waiting task
335    _xcu_send_wti( remote_xy,    // cluster index
336                   lpid,         // local processor index
337                   0 );          // don't force context switch if not idle
338
339#if GIET_DEBUG_IRQS  // we don't take the TTY lock to avoid deadlock
340unsigned int x              = cluster_xy >> Y_WIDTH;
341unsigned int y              = cluster_xy & ((1<<Y_WIDTH)-1);
342unsigned int rx             = remote_xy >> Y_WIDTH;
343unsigned int ry             = remote_xy & ((1<<Y_WIDTH)-1);
344unsigned int rlpid          = rprocid % NB_PROCS_MAX;
345_puts("\n[IRQS DEBUG] Processor[");
346_putd(x );
347_puts(",");
348_putd(y );
349_puts(",");
350_putd(lpid );
351_puts("] enters _bdv_isr() at cycle ");
352_putd(_get_proctime() );
353_puts("\n  for task ");
354_putd(ltid );
355_puts(" running on processor[");
356_putd(rx );
357_puts(",");
358_putd(ry );
359_puts(",");
360_putd(rlpid );
361_puts(" / bdv status = ");
362_putx(_bdv_status );
363_puts("\n");
364#endif
365
366}
367
368
369// Local Variables:
370// tab-width: 4
371// c-basic-offset: 4
372// c-file-offsets:((innamespace . 0)(inline-open . 0))
373// indent-tabs-mode: nil
374// End:
375// vim: filetype=c:expandtab:shiftwidth=4:tabstop=4:softtabstop=4
376
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