4 * Copyright (C) 2000-2012 Imagination Technologies.
6 * This program is free software; you can redistribute it and/or modify it under
7 * the terms of the GNU General Public License version 2 as published by the
8 * Free Software Foundation.
10 * Thread binary interface header
13 #ifndef _ASM_METAG_TBX_H_
14 #define _ASM_METAG_TBX_H_
16 /* for CACHEW_* values */
17 #include <asm/metag_isa.h>
18 /* for LINSYSEVENT_* addresses */
19 #include <asm/metag_mem.h>
22 #ifndef TBI_MUTEXES_1_4
23 #define TBI_MUTEXES_1_4
25 #ifndef TBI_SEMAPHORES_1_4
26 #define TBI_SEMAPHORES_1_4
28 #ifndef TBI_ASYNC_SWITCH_1_4
29 #define TBI_ASYNC_SWITCH_1_4
31 #ifndef TBI_FASTINT_1_4
32 #define TBI_FASTINT_1_4
37 /* Id values in the TBI system describe a segment using an arbitrary
38 integer value and flags in the bottom 8 bits, the SIGPOLL value is
39 used in cases where control over blocking or polling behaviour is
41 #define TBID_SIGPOLL_BIT 0x02 /* Set bit in an Id value to poll vs block */
42 /* Extended segment identifiers use strings in the string table */
43 #define TBID_IS_SEGSTR( Id ) (((Id) & (TBID_SEGTYPE_BITS>>1)) == 0)
45 /* Segment identifiers contain the following related bit-fields */
46 #define TBID_SEGTYPE_BITS 0x0F /* One of the predefined segment types */
47 #define TBID_SEGTYPE_S 0
48 #define TBID_SEGSCOPE_BITS 0x30 /* Indicates the scope of the segment */
49 #define TBID_SEGSCOPE_S 4
50 #define TBID_SEGGADDR_BITS 0xC0 /* Indicates access possible via pGAddr */
51 #define TBID_SEGGADDR_S 6
53 /* Segments of memory can only really contain a few types of data */
54 #define TBID_SEGTYPE_TEXT 0x02 /* Code segment */
55 #define TBID_SEGTYPE_DATA 0x04 /* Data segment */
56 #define TBID_SEGTYPE_STACK 0x06 /* Stack segment */
57 #define TBID_SEGTYPE_HEAP 0x0A /* Heap segment */
58 #define TBID_SEGTYPE_ROOT 0x0C /* Root block segments */
59 #define TBID_SEGTYPE_STRING 0x0E /* String table segment */
61 /* Segments have one of three possible scopes */
62 #define TBID_SEGSCOPE_INIT 0 /* Temporary area for initialisation phase */
63 #define TBID_SEGSCOPE_LOCAL 1 /* Private to this thread */
64 #define TBID_SEGSCOPE_GLOBAL 2 /* Shared globally throughout the system */
65 #define TBID_SEGSCOPE_SHARED 3 /* Limited sharing between local/global */
67 /* For segment specifier a further field in two of the remaining bits
68 indicates the usefulness of the pGAddr field in the segment descriptor
70 #define TBID_SEGGADDR_NULL 0 /* pGAddr is NULL -> SEGSCOPE_(LOCAL|INIT) */
71 #define TBID_SEGGADDR_READ 1 /* Only read via pGAddr */
72 #define TBID_SEGGADDR_WRITE 2 /* Full access via pGAddr */
73 #define TBID_SEGGADDR_EXEC 3 /* Only execute via pGAddr */
75 /* The following values are common to both segment and signal Id value and
76 live in the top 8 bits of the Id values. */
78 /* The ISTAT bit indicates if segments are related to interrupt vs
79 background level interfaces a thread can still handle all triggers at
80 either level, but can also split these up if it wants to. */
81 #define TBID_ISTAT_BIT 0x01000000
82 #define TBID_ISTAT_S 24
84 /* Privilege needed to access a segment is indicated by the next bit.
86 This bit is set to mirror the current privilege level when starting a
87 search for a segment - setting it yourself toggles the automatically
88 generated state which is only useful to emulate unprivileged behaviour
89 or access unprivileged areas of memory while at privileged level. */
90 #define TBID_PSTAT_BIT 0x02000000
91 #define TBID_PSTAT_S 25
93 /* The top six bits of a signal/segment specifier identifies a thread within
94 the system. This represents a segments owner. */
95 #define TBID_THREAD_BITS 0xFC000000
96 #define TBID_THREAD_S 26
98 /* Special thread id values */
99 #define TBID_THREAD_NULL (-32) /* Never matches any thread/segment id used */
100 #define TBID_THREAD_GLOBAL (-31) /* Things global to all threads */
101 #define TBID_THREAD_HOST ( -1) /* Host interface */
102 #define TBID_THREAD_EXTIO (TBID_THREAD_HOST) /* Host based ExtIO i/f */
104 /* Virtual Id's are used for external thread interface structures or the
105 above special Id's */
106 #define TBID_IS_VIRTTHREAD( Id ) ((Id) < 0)
108 /* Real Id's are used for actual hardware threads that are local */
109 #define TBID_IS_REALTHREAD( Id ) ((Id) >= 0)
111 /* Generate a segment Id given Thread, Scope, and Type */
112 #define TBID_SEG( Thread, Scope, Type ) (\
113 ((Thread)<<TBID_THREAD_S) + ((Scope)<<TBID_SEGSCOPE_S) + (Type))
115 /* Generate a signal Id given Thread and SigNum */
116 #define TBID_SIG( Thread, SigNum ) (\
117 ((Thread)<<TBID_THREAD_S) + ((SigNum)<<TBID_SIGNUM_S) + TBID_SIGNAL_BIT)
119 /* Generate an Id that solely represents a thread - useful for cache ops */
120 #define TBID_THD( Thread ) ((Thread)<<TBID_THREAD_S)
121 #define TBID_THD_NULL ((TBID_THREAD_NULL) <<TBID_THREAD_S)
122 #define TBID_THD_GLOBAL ((TBID_THREAD_GLOBAL)<<TBID_THREAD_S)
124 /* Common exception handler (see TBID_SIGNUM_XXF below) receives hardware
125 generated fault codes TBIXXF_SIGNUM_xxF in it's SigNum parameter */
126 #define TBIXXF_SIGNUM_IIF 0x01 /* General instruction fault */
127 #define TBIXXF_SIGNUM_PGF 0x02 /* Privilege general fault */
128 #define TBIXXF_SIGNUM_DHF 0x03 /* Data access watchpoint HIT */
129 #define TBIXXF_SIGNUM_IGF 0x05 /* Code fetch general read failure */
130 #define TBIXXF_SIGNUM_DGF 0x07 /* Data access general read/write fault */
131 #define TBIXXF_SIGNUM_IPF 0x09 /* Code fetch page fault */
132 #define TBIXXF_SIGNUM_DPF 0x0B /* Data access page fault */
133 #define TBIXXF_SIGNUM_IHF 0x0D /* Instruction breakpoint HIT */
134 #define TBIXXF_SIGNUM_DWF 0x0F /* Data access read-only fault */
136 /* Hardware signals communicate events between processing levels within a
137 single thread all the _xxF cases are exceptions and are routed via a
138 common exception handler, _SWx are software trap events and kicks including
139 __TBISignal generated kicks, and finally _TRx are hardware triggers */
140 #define TBID_SIGNUM_SW0 0x00 /* SWITCH GROUP 0 - Per thread user */
141 #define TBID_SIGNUM_SW1 0x01 /* SWITCH GROUP 1 - Per thread system */
142 #define TBID_SIGNUM_SW2 0x02 /* SWITCH GROUP 2 - Internal global request */
143 #define TBID_SIGNUM_SW3 0x03 /* SWITCH GROUP 3 - External global request */
145 #define TBID_SIGNUM_FPE 0x04 /* Deferred exception - Any IEEE 754 exception */
146 #define TBID_SIGNUM_FPD 0x05 /* Deferred exception - Denormal exception */
147 /* Reserved 0x6 for a reserved deferred exception */
148 #define TBID_SIGNUM_BUS 0x07 /* Deferred exception - Bus Error */
149 /* Reserved 0x08-0x09 */
151 /* Reserved 0x04-0x09 */
153 #define TBID_SIGNUM_SWS 0x0A /* KICK received with SigMask != 0 */
154 #define TBID_SIGNUM_SWK 0x0B /* KICK received with SigMask == 0 */
155 /* Reserved 0x0C-0x0F */
156 #define TBID_SIGNUM_TRT 0x10 /* Timer trigger */
157 #define TBID_SIGNUM_LWK 0x11 /* Low level kick (handler provided by TBI) */
158 #define TBID_SIGNUM_XXF 0x12 /* Fault handler - receives ALL _xxF sigs */
160 #define TBID_SIGNUM_DFR 0x13 /* Deferred Exception handler */
162 #define TBID_SIGNUM_FPE 0x13 /* FPE Exception handler */
164 /* External trigger one group 0x14 to 0x17 - per thread */
165 #define TBID_SIGNUM_TR1(Thread) (0x14+(Thread))
166 #define TBID_SIGNUM_T10 0x14
167 #define TBID_SIGNUM_T11 0x15
168 #define TBID_SIGNUM_T12 0x16
169 #define TBID_SIGNUM_T13 0x17
170 /* External trigger two group 0x18 to 0x1b - per thread */
171 #define TBID_SIGNUM_TR2(Thread) (0x18+(Thread))
172 #define TBID_SIGNUM_T20 0x18
173 #define TBID_SIGNUM_T21 0x19
174 #define TBID_SIGNUM_T22 0x1A
175 #define TBID_SIGNUM_T23 0x1B
176 #define TBID_SIGNUM_TR3 0x1C /* External trigger N-4 (global) */
177 #define TBID_SIGNUM_TR4 0x1D /* External trigger N-3 (global) */
178 #define TBID_SIGNUM_TR5 0x1E /* External trigger N-2 (global) */
179 #define TBID_SIGNUM_TR6 0x1F /* External trigger N-1 (global) */
180 #define TBID_SIGNUM_MAX 0x1F
182 /* Return the trigger register(TXMASK[I]/TXSTAT[I]) bits related to
183 each hardware signal, sometimes this is a many-to-one relationship. */
184 #define TBI_TRIG_BIT(SigNum) (\
185 ((SigNum) >= TBID_SIGNUM_TRT) ? 1<<((SigNum)-TBID_SIGNUM_TRT) :\
186 ( ((SigNum) == TBID_SIGNUM_SWS) || \
187 ((SigNum) == TBID_SIGNUM_SWK) ) ? \
188 TXSTAT_KICK_BIT : TXSTATI_BGNDHALT_BIT )
190 /* Return the hardware trigger vector number for entries in the
191 HWVEC0EXT table that will generate the required internal trigger. */
192 #define TBI_TRIG_VEC(SigNum) (\
193 ((SigNum) >= TBID_SIGNUM_T10) ? ((SigNum)-TBID_SIGNUM_TRT) : -1)
195 /* Default trigger masks for each thread at background/interrupt level */
196 #define TBI_TRIGS_INIT( Thread ) (\
197 TXSTAT_KICK_BIT + TBI_TRIG_BIT(TBID_SIGNUM_TR1(Thread)) )
198 #define TBI_INTS_INIT( Thread ) (\
199 TXSTAT_KICK_BIT + TXSTATI_BGNDHALT_BIT \
200 + TBI_TRIG_BIT(TBID_SIGNUM_TR2(Thread)) )
203 /* A spin-lock location is a zero-initialised location in memory */
204 typedef volatile int TBISPIN, *PTBISPIN;
206 /* A kick location is a hardware location you can write to
207 * in order to cause a kick
209 typedef volatile int *PTBIKICK;
211 #if defined(METAC_1_0) || defined(METAC_1_1)
212 /* Macro to perform a kick */
213 #define TBI_KICK( pKick ) do { pKick[0] = 1; } while (0)
215 /* #define METAG_LIN_VALUES before including machine.h if required */
216 #ifdef LINSYSEVENT_WR_COMBINE_FLUSH
217 /* Macro to perform a kick - write combiners must be flushed */
218 #define TBI_KICK( pKick ) do {\
219 volatile int *pFlush = (volatile int *) LINSYSEVENT_WR_COMBINE_FLUSH; \
221 pKick[0] = 1; } while (0)
223 #endif /* if defined(METAC_1_0) || defined(METAC_1_1) */
224 #endif /* ifndef __ASSEMBLY__ */
227 /* 64-bit dual unit state value */
228 typedef struct _tbidual_tag_ {
229 /* 32-bit value from a pair of registers in data or address units */
231 } TBIDUAL, *PTBIDUAL;
232 #endif /* ifndef __ASSEMBLY__ */
234 /* Byte offsets of fields within TBIDUAL */
235 #define TBIDUAL_U0 (0)
236 #define TBIDUAL_U1 (4)
238 #define TBIDUAL_BYTES (8)
240 #define TBICTX_CRIT_BIT 0x0001 /* ASync state saved in TBICTX */
241 #define TBICTX_SOFT_BIT 0x0002 /* Sync state saved in TBICTX (other bits 0) */
242 #ifdef TBI_FASTINT_1_4
243 #define TBICTX_FINT_BIT 0x0004 /* Using Fast Interrupts */
245 #define TBICTX_FPAC_BIT 0x0010 /* FPU state in TBICTX, FPU active on entry */
246 #define TBICTX_XMCC_BIT 0x0020 /* Bit to identify a MECC task */
247 #define TBICTX_CBUF_BIT 0x0040 /* Hardware catch buffer flag from TXSTATUS */
248 #define TBICTX_CBRP_BIT 0x0080 /* Read pipeline dirty from TXDIVTIME */
249 #define TBICTX_XDX8_BIT 0x0100 /* Saved DX.8 to DX.15 too */
250 #define TBICTX_XAXX_BIT 0x0200 /* Save remaining AX registers to AX.7 */
251 #define TBICTX_XHL2_BIT 0x0400 /* Saved hardware loop registers too */
252 #define TBICTX_XTDP_BIT 0x0800 /* Saved DSP registers too */
253 #define TBICTX_XEXT_BIT 0x1000 /* Set if TBICTX.Ext.Ctx contains extended
254 state save area, otherwise TBICTX.Ext.AX2
255 just holds normal A0.2 and A1.2 states */
256 #define TBICTX_WAIT_BIT 0x2000 /* Causes wait for trigger - sticky toggle */
257 #define TBICTX_XCBF_BIT 0x4000 /* Catch buffer or RD extracted into TBICTX */
258 #define TBICTX_PRIV_BIT 0x8000 /* Set if system uses 'privileged' model */
261 #define TBICTX_XAX3_BIT 0x0200 /* Saved AX.5 to AX.7 for XAXX */
262 #define TBICTX_AX_REGS 5 /* Ax.0 to Ax.4 are core GP regs on CHORUS */
264 #define TBICTX_XAX4_BIT 0x0200 /* Saved AX.4 to AX.7 for XAXX */
265 #define TBICTX_AX_REGS 4 /* Default is Ax.0 to Ax.3 */
269 #define TBICTX_CFGFPU_FX16_BIT 0x00010000 /* Save FX.8 to FX.15 too */
271 /* The METAC_CORE_ID_CONFIG field indicates omitted DSP resources */
272 #define METAC_COREID_CFGXCTX_MASK( Value ) (\
273 ( (((Value & METAC_COREID_CFGDSP_BITS)>> \
274 METAC_COREID_CFGDSP_S ) == METAC_COREID_CFGDSP_MIN) ? \
275 ~(TBICTX_XHL2_BIT+TBICTX_XTDP_BIT+ \
276 TBICTX_XAXX_BIT+TBICTX_XDX8_BIT ) : ~0U ) )
279 /* Extended context state provides a standardised method for registering the
280 arguments required by __TBICtxSave to save the additional register states
281 currently in use by non general purpose code. The state of the __TBIExtCtx
282 variable in the static space of the thread forms an extension of the base
283 context of the thread.
285 If ( __TBIExtCtx.Ctx.SaveMask == 0 ) then pExt is assumed to be NULL and
286 the empty state of __TBIExtCtx is represented by the fact that
287 TBICTX.SaveMask does not have the bit TBICTX_XEXT_BIT set.
289 If ( __TBIExtCtx.Ctx.SaveMask != 0 ) then pExt should point at a suitably
290 sized extended context save area (usually at the end of the stack space
291 allocated by the current routine). This space should allow for the
292 displaced state of A0.2 and A1.2 to be saved along with the other extended
293 states indicated via __TBIExtCtx.Ctx.SaveMask. */
295 typedef union _tbiextctx_tag_ {
298 struct _tbiextctxext_tag {
300 short DspramSizes; /* DSPRAM sizes. Encoding varies between
301 TBICtxAlloc and the ECH scheme. */
305 short SaveMask; /* Flag bits for state saved */
306 PTBIDUAL pExt; /* AX[2] state saved first plus Xxxx state */
310 } TBIEXTCTX, *PTBIEXTCTX;
312 /* Automatic registration of extended context save for __TBINestInts */
313 extern TBIEXTCTX __TBIExtCtx;
314 #endif /* ifndef __ASSEMBLY__ */
316 /* Byte offsets of fields within TBIEXTCTX */
317 #define TBIEXTCTX_AX2 (0)
318 #define TBIEXTCTX_Ctx (0)
319 #define TBIEXTCTX_Ctx_SaveMask (TBIEXTCTX_Ctx + 2)
320 #define TBIEXTCTX_Ctx_pExt (TBIEXTCTX_Ctx + 2 + 2)
322 /* Extended context data size calculation constants */
323 #define TBICTXEXT_BYTES (8)
324 #define TBICTXEXTBB8_BYTES (8*8)
325 #define TBICTXEXTAX3_BYTES (3*8)
326 #define TBICTXEXTAX4_BYTES (4*8)
328 #define TBICTXEXTAXX_BYTES TBICTXEXTAX3_BYTES
330 #define TBICTXEXTAXX_BYTES TBICTXEXTAX4_BYTES
332 #define TBICTXEXTHL2_BYTES (3*8)
333 #define TBICTXEXTTDR_BYTES (27*8)
334 #define TBICTXEXTTDP_BYTES TBICTXEXTTDR_BYTES
337 #define TBICTXEXTFX8_BYTES (4*8)
338 #define TBICTXEXTFPAC_BYTES (1*4 + 2*2 + 4*8)
339 #define TBICTXEXTFACF_BYTES (3*8)
342 /* Maximum flag bits to be set via the TBICTX_EXTSET macro */
343 #define TBICTXEXT_MAXBITS (TBICTX_XEXT_BIT| \
344 TBICTX_XDX8_BIT|TBICTX_XAXX_BIT|\
345 TBICTX_XHL2_BIT|TBICTX_XTDP_BIT )
347 /* Maximum size of the extended context save area for current variant */
348 #define TBICTXEXT_MAXBYTES (TBICTXEXT_BYTES+TBICTXEXTBB8_BYTES+\
349 TBICTXEXTAXX_BYTES+TBICTXEXTHL2_BYTES+\
352 #ifdef TBI_FASTINT_1_4
353 /* Maximum flag bits to be set via the TBICTX_EXTSET macro */
354 #define TBICTX2EXT_MAXBITS (TBICTX_XDX8_BIT|TBICTX_XAXX_BIT|\
355 TBICTX_XHL2_BIT|TBICTX_XTDP_BIT )
357 /* Maximum size of the extended context save area for current variant */
358 #define TBICTX2EXT_MAXBYTES (TBICTXEXTBB8_BYTES+TBICTXEXTAXX_BYTES\
359 +TBICTXEXTHL2_BYTES+TBICTXEXTTDP_BYTES )
362 /* Specify extended resources being used by current routine, code must be
363 assembler generated to utilise extended resources-
365 MOV D0xxx,A0StP ; Perform alloca - routine should
366 ADD A0StP,A0StP,#SaveSize ; setup/use A0FrP to access locals
367 MOVT D1xxx,#SaveMask ; TBICTX_XEXT_BIT MUST be set
368 SETL [A1GbP+#OG(___TBIExtCtx)],D0xxx,D1xxx
370 NB: OG(___TBIExtCtx) is a special case supported for SETL/GETL operations
371 on 64-bit sizes structures only, other accesses must be based on use
372 of OGA(___TBIExtCtx).
376 MOV D0xxx,#0 ; Clear extended context save state
378 SETL [A1GbP+#OG(___TBIExtCtx)],D0xxx,D1xxx
379 SUB A0StP,A0StP,#SaveSize ; If original A0StP required
381 NB: Both the setting and clearing of the whole __TBIExtCtx MUST be done
382 atomically in one 64-bit write operation.
384 For simple interrupt handling only via __TBINestInts there should be no
385 impact of the __TBIExtCtx system. If pre-emptive scheduling is being
386 performed however (assuming __TBINestInts has already been called earlier
387 on) then the following logic will correctly call __TBICtxSave if required
388 and clear out the currently selected background task-
390 if ( __TBIExtCtx.Ctx.SaveMask & TBICTX_XEXT_BIT )
392 / * Store extended states in pCtx * /
393 State.Sig.SaveMask |= __TBIExtCtx.Ctx.SaveMask;
395 (void) __TBICtxSave( State, (void *) __TBIExtCtx.Ctx.pExt );
399 and when restoring task states call __TBICtxRestore-
401 / * Restore state from pCtx * /
402 State.Sig.pCtx = pCtx;
403 State.Sig.SaveMask = pCtx->SaveMask;
405 if ( State.Sig.SaveMask & TBICTX_XEXT_BIT )
407 / * Restore extended states from pCtx * /
408 __TBIExtCtx.Val = pCtx->Ext.Val;
410 (void) __TBICtxRestore( State, (void *) __TBIExtCtx.Ctx.pExt );
415 /* Critical thread state save area */
417 typedef struct _tbictx_tag_ {
418 /* TXSTATUS_FLAG_BITS and TXSTATUS_LSM_STEP_BITS from TXSTATUS */
420 /* Mask indicates any extended context state saved; 0 -> Never run */
424 /* Saved critical register states */
426 /* Background control register states - for cores without catch buffer
427 base in DIVTIME the TXSTATUS bits RPVALID and RPMASK are stored with
428 the real state TXDIVTIME in CurrDIVTIME */
429 int CurrRPT, CurrBPOBITS, CurrMODE, CurrDIVTIME;
430 /* Saved AX register states */
433 TBIDUAL AX3[TBICTX_AX_REGS-3];
435 /* Any CBUF state to be restored by a handler return must be stored here.
436 Other extended state can be stored anywhere - see __TBICtxSave and
441 #ifdef TBI_FASTINT_1_4
442 typedef struct _tbictx2_tag_ {
443 TBIDUAL AX[2]; /* AU.0, AU.1 */
444 TBIDUAL DX[2]; /* DU.0, DU.4 */
448 void *CurrPC; /* PC in PC address space */
449 } TBICTX2, *PTBICTX2;
450 /* TBICTX2 is followed by:
451 * TBICTXEXTCB0 if TXSTATUS.CBMarker
452 * TBIDUAL * TXSTATUS.IRPCount if TXSTATUS.IRPCount > 0
453 * TBICTXGP if using __TBIStdRootIntHandler or __TBIStdCtxSwitchRootIntHandler
456 typedef struct _tbictxgp_tag_ {
460 TBIDUAL DX[6]; /* DU.1-DU.3, DU.5-DU.7 */
461 TBIDUAL AX[2]; /* AU.2-AU.3 */
462 } TBICTXGP, *PTBICTXGP;
464 #define TBICTXGP_DspramSizes (0)
465 #define TBICTXGP_SaveMask (TBICTXGP_DspramSizes + 2)
466 #define TBICTXGP_MAX_BYTES (2 + 2 + 4 + 8*(6+2))
469 #endif /* ifndef __ASSEMBLY__ */
471 /* Byte offsets of fields within TBICTX */
472 #define TBICTX_Flags (0)
473 #define TBICTX_SaveMask (2)
474 #define TBICTX_CurrPC (4)
475 #define TBICTX_DX (2 + 2 + 4)
476 #define TBICTX_CurrRPT (2 + 2 + 4 + 8 * 8)
477 #define TBICTX_CurrMODE (2 + 2 + 4 + 8 * 8 + 4 + 4)
478 #define TBICTX_AX (2 + 2 + 4 + 8 * 8 + 4 + 4 + 4 + 4)
479 #define TBICTX_Ext (2 + 2 + 4 + 8 * 8 + 4 + 4 + 4 + 4 + 2 * 8)
480 #define TBICTX_Ext_AX2 (TBICTX_Ext + TBIEXTCTX_AX2)
481 #define TBICTX_Ext_AX2_U0 (TBICTX_Ext + TBIEXTCTX_AX2 + TBIDUAL_U0)
482 #define TBICTX_Ext_AX2_U1 (TBICTX_Ext + TBIEXTCTX_AX2 + TBIDUAL_U1)
483 #define TBICTX_Ext_Ctx_pExt (TBICTX_Ext + TBIEXTCTX_Ctx_pExt)
484 #define TBICTX_Ext_Ctx_SaveMask (TBICTX_Ext + TBIEXTCTX_Ctx_SaveMask)
486 #ifdef TBI_FASTINT_1_4
487 #define TBICTX2_BYTES (8 * 2 + 8 * 2 + 4 + 4 + 4 + 4)
488 #define TBICTXEXTCB0_BYTES (4 + 4 + 8)
490 #define TBICTX2_CRIT_MAX_BYTES (TBICTX2_BYTES + TBICTXEXTCB0_BYTES + 6 * TBIDUAL_BYTES)
491 #define TBI_SWITCH_NEXT_PC(PC, EXTRA) ((PC) + (EXTRA & 1) ? 8 : 4)
495 /* Extended thread state save areas - catch buffer state element */
496 typedef struct _tbictxextcb0_tag_ {
497 /* Flags data and address value - see METAC_CATCH_VALUES in machine.h */
498 unsigned long CBFlags, CBAddr;
502 } TBICTXEXTCB0, *PTBICTXEXTCB0;
504 /* Read pipeline state saved on later cores after single catch buffer slot */
505 typedef struct _tbictxextrp6_tag_ {
506 /* RPMask is TXSTATUS_RPMASK_BITS only, reserved is undefined */
507 unsigned long RPMask, Reserved0;
510 } TBICTXEXTRP6, *PTBICTXEXTRP6;
512 /* Extended thread state save areas - 8 DU register pairs */
513 typedef struct _tbictxextbb8_tag_ {
514 /* Remaining Data unit registers in 64-bit pairs */
517 } TBICTXEXTBB8, *PTBICTXEXTBB8;
519 /* Extended thread state save areas - 3 AU register pairs */
520 typedef struct _tbictxextbb3_tag_ {
521 /* Remaining Address unit registers in 64-bit pairs */
524 } TBICTXEXTBB3, *PTBICTXEXTBB3;
526 /* Extended thread state save areas - 4 AU register pairs or 4 FX pairs */
527 typedef struct _tbictxextbb4_tag_ {
528 /* Remaining Address unit or FPU registers in 64-bit pairs */
531 } TBICTXEXTBB4, *PTBICTXEXTBB4;
533 /* Extended thread state save areas - Hardware loop states (max 2) */
534 typedef struct _tbictxexthl2_tag_ {
535 /* Hardware looping register states */
536 TBIDUAL Start, End, Count;
538 } TBICTXEXTHL2, *PTBICTXEXTHL2;
540 /* Extended thread state save areas - DSP register states */
541 typedef struct _tbictxexttdp_tag_ {
542 /* DSP 32-bit accumulator register state (Bits 31:0 of ACX.0) */
544 /* DSP > 32-bit accumulator bits 63:32 of ACX.0 (zero-extended) */
546 /* Twiddle register state, and three phase increment states */
548 /* Modulo region size, padded to 64-bits */
549 int CurrMRSIZE, Reserved0;
551 } TBICTXEXTTDP, *PTBICTXEXTTDP;
553 /* Extended thread state save areas - DSP register states including DSP RAM */
554 typedef struct _tbictxexttdpr_tag_ {
555 /* DSP 32-bit accumulator register state (Bits 31:0 of ACX.0) */
557 /* DSP 40-bit accumulator register state (Bits 39:8 of ACX.0) */
559 /* DSP RAM Pointers */
560 TBIDUAL RP0[2], WP0[2], RP1[2], WP1[2];
561 /* DSP RAM Increments */
562 TBIDUAL RPI0[2], WPI0[2], RPI1[2], WPI1[2];
563 /* Template registers */
564 unsigned long Tmplt[16];
565 /* Modulo address region size and DSP RAM module region sizes */
566 int CurrMRSIZE, CurrDRSIZE;
568 } TBICTXEXTTDPR, *PTBICTXEXTTDPR;
571 /* The METAC_ID_CORE register state is a marker for the FPU
572 state that is then stored after this core header structure. */
573 #define TBICTXEXTFPU_CONFIG_MASK ( (METAC_COREID_NOFPACC_BIT+ \
574 METAC_COREID_CFGFPU_BITS ) << \
575 METAC_COREID_CONFIG_BITS )
577 /* Recorded FPU exception state from TXDEFR in DefrFpu */
578 #define TBICTXEXTFPU_DEFRFPU_MASK (TXDEFR_FPU_FE_BITS)
580 /* Extended thread state save areas - FPU register states */
581 typedef struct _tbictxextfpu_tag_ {
582 /* Stored METAC_CORE_ID CONFIG */
584 /* Stored deferred TXDEFR bits related to FPU
586 * This is encoded as follows in order to fit into 16-bits:
587 * DefrFPU:15 - 14 <= 0
588 * :13 - 8 <= TXDEFR:21-16
590 * : 5 - 0 <= TXDEFR:5-0
594 /* TXMODE bits related to FPU */
597 /* FPU Even/Odd register states */
600 /* if CfgFpu & TBICTX_CFGFPU_FX16_BIT -> 1 then TBICTXEXTBB4 holds FX.8-15 */
601 /* if CfgFpu & TBICTX_CFGFPU_NOACF_BIT -> 0 then TBICTXEXTFPACC holds state */
602 } TBICTXEXTFPU, *PTBICTXEXTFPU;
604 /* Extended thread state save areas - FPU accumulator state */
605 typedef struct _tbictxextfpacc_tag_ {
606 /* FPU accumulator register state - three 64-bit parts */
609 } TBICTXEXTFPACC, *PTBICTXEXTFPACC;
612 /* Prototype TBI structure */
615 /* A 64-bit return value used commonly in the TBI APIs */
616 typedef union _tbires_tag_ {
617 /* Save and load this value to get/set the whole result quickly */
620 /* Parameter of a fnSigs or __TBICtx* call */
621 struct _tbires_sig_tag_ {
622 /* TXMASK[I] bits zeroed upto and including current trigger level */
623 unsigned short TrigMask;
624 /* Control bits for handlers - see PTBIAPIFN documentation below */
625 unsigned short SaveMask;
626 /* Pointer to the base register context save area of the thread */
630 /* Result of TBIThrdPrivId call */
631 struct _tbires_thrdprivid_tag_ {
632 /* Basic thread identifier; just TBID_THREAD_BITS */
634 /* None thread number bits; TBID_ISTAT_BIT+TBID_PSTAT_BIT */
638 /* Parameter and Result of a __TBISwitch call */
639 struct _tbires_switch_tag_ {
640 /* Parameter passed across context switch */
642 /* Thread context of other Thread includng restore flags */
646 /* For extended S/W events only */
647 struct _tbires_ccb_tag_ {
652 struct _tbires_tlb_tag_ {
653 int Leaf; /* TLB Leaf data */
654 int Flags; /* TLB Flags */
657 #ifdef TBI_FASTINT_1_4
658 struct _tbires_intr_tag_ {
666 #endif /* ifndef __ASSEMBLY__ */
669 /* Prototype for all signal handler functions, called via ___TBISyncTrigger or
672 State.Sig.TrigMask will indicate the bits set within TXMASKI at
673 the time of the handler call that have all been cleared to prevent
674 nested interrupt occuring immediately.
676 State.Sig.SaveMask is a bit-mask which will be set to Zero when a trigger
677 occurs at background level and TBICTX_CRIT_BIT and optionally
678 TBICTX_CBUF_BIT when a trigger occurs at interrupt level.
680 TBICTX_CBUF_BIT reflects the state of TXSTATUS_CBMARKER_BIT for
681 the interrupted background thread.
683 State.Sig.pCtx will point at a TBICTX structure generated to hold the
684 critical state of the interrupted thread at interrupt level and
685 should be set to NULL when called at background level.
687 Triggers will indicate the status of TXSTAT or TXSTATI sampled by the
688 code that called the handler.
690 InstOrSWSId is defined firstly as 'Inst' if the SigNum is TBID_SIGNUM_SWx
691 and hold the actual SWITCH instruction detected, secondly if SigNum
692 is TBID_SIGNUM_SWS the 'SWSId' is defined to hold the Id of the
693 software signal detected, in other cases the value of this
694 parameter is undefined.
696 pTBI points at the PTBI structure related to the thread and processing
699 TBIRES return value at both processing levels is similar in terms of any
700 changes that the handler makes. By default the State argument value
701 passed in should be returned.
703 Sig.TrigMask value is bits to OR back into TXMASKI when the handler
704 completes to enable currently disabled interrupts.
706 Sig.SaveMask value is ignored.
711 typedef TBIRES (*PTBIAPIFN)( TBIRES State, int SigNum,
712 int Triggers, int InstOrSWSId,
713 volatile struct _tbi_tag_ *pTBI );
714 #endif /* ifndef __ASSEMBLY__ */
717 /* The global memory map is described by a list of segment descriptors */
718 typedef volatile struct _tbiseg_tag_ {
719 volatile struct _tbiseg_tag_ *pLink;
720 int Id; /* Id of the segment */
721 TBISPIN Lock; /* Spin-lock for struct (normally 0) */
722 unsigned int Bytes; /* Size of region in bytes */
723 void *pGAddr; /* Base addr of region in global space */
724 void *pLAddr; /* Base addr of region in local space */
725 int Data[2]; /* Segment specific data (may be extended) */
728 #endif /* ifndef __ASSEMBLY__ */
730 /* Offsets of fields in TBISEG structure */
731 #define TBISEG_pLink ( 0)
732 #define TBISEG_Id ( 4)
733 #define TBISEG_Lock ( 8)
734 #define TBISEG_Bytes (12)
735 #define TBISEG_pGAddr (16)
736 #define TBISEG_pLAddr (20)
737 #define TBISEG_Data (24)
740 typedef volatile struct _tbi_tag_ {
741 int SigMask; /* Bits set to represent S/W events */
742 PTBIKICK pKick; /* Kick addr for S/W events */
743 void *pCCB; /* Extended S/W events */
744 PTBISEG pSeg; /* Related segment structure */
745 PTBIAPIFN fnSigs[TBID_SIGNUM_MAX+1];/* Signal handler API table */
747 #endif /* ifndef __ASSEMBLY__ */
749 /* Byte offsets of fields within TBI */
750 #define TBI_SigMask (0)
751 #define TBI_pKick (4)
753 #define TBI_pSeg (12)
754 #define TBI_fnSigs (16)
758 /* This handler should be used for TBID_SIGNUM_DFR */
759 extern TBIRES __TBIHandleDFR ( TBIRES State, int SigNum,
760 int Triggers, int InstOrSWSId,
761 volatile struct _tbi_tag_ *pTBI );
765 /* String table entry - special values */
766 #define METAG_TBI_STRS (0x5300) /* Tag : If entry is valid */
767 #define METAG_TBI_STRE (0x4500) /* Tag : If entry is end of table */
768 #define METAG_TBI_STRG (0x4700) /* Tag : If entry is a gap */
769 #define METAG_TBI_STRX (0x5A00) /* TransLen : If no translation present */
772 typedef volatile struct _tbistr_tag_ {
773 short Bytes; /* Length of entry in Bytes */
774 short Tag; /* Normally METAG_TBI_STRS(0x5300) */
775 short Len; /* Length of the string entry (incl null) */
776 short TransLen; /* Normally METAG_TBI_STRX(0x5A00) */
777 char String[8]; /* Zero terminated (may-be bigger) */
780 #endif /* ifndef __ASSEMBLY__ */
782 /* Cache size information - available as fields of Data[1] of global heap
784 #define METAG_TBI_ICACHE_SIZE_S 0 /* see comments below */
785 #define METAG_TBI_ICACHE_SIZE_BITS 0x0000000F
786 #define METAG_TBI_ICACHE_FILL_S 4
787 #define METAG_TBI_ICACHE_FILL_BITS 0x000000F0
788 #define METAG_TBI_DCACHE_SIZE_S 8
789 #define METAG_TBI_DCACHE_SIZE_BITS 0x00000F00
790 #define METAG_TBI_DCACHE_FILL_S 12
791 #define METAG_TBI_DCACHE_FILL_BITS 0x0000F000
793 /* METAG_TBI_xCACHE_SIZE
794 Describes the physical cache size rounded up to the next power of 2
795 relative to a 16K (2^14) cache. These sizes are encoded as a signed addend
796 to this base power of 2, for example
797 4K -> 2^12 -> -2 (i.e. 12-14)
804 METAG_TBI_xCACHE_FILL
805 Describes the physical cache size within the power of 2 area given by
806 the value above. For example a 10K cache may be represented as having
807 nearest size 16K with a fill of 10 sixteenths. This is encoded as the
808 number of unused 1/16ths, for example
816 #define METAG_TBI_CACHE_SIZE_BASE_LOG2 14
818 /* Each declaration made by this macro generates a TBISTR entry */
820 #define TBISTR_DECL( Name, Str ) \
821 __attribute__ ((__section__ (".tbistr") )) const char Name[] = #Str
824 /* META timer values - see below for Timer support routines */
825 #define TBI_TIMERWAIT_MIN (-16) /* Minimum 'recommended' period */
826 #define TBI_TIMERWAIT_MAX (-0x7FFFFFFF) /* Maximum 'recommended' period */
829 /* These macros allow direct access from C to any register known to the
830 assembler or defined in machine.h. Example candidates are TXTACTCYC,
831 TXIDLECYC, and TXPRIVEXT. Note that when higher level macros and routines
832 like the timer and trigger handling features below these should be used in
833 preference to this direct low-level access mechanism. */
834 #define TBI_GETREG( Reg ) __extension__ ({\
836 __asm__ volatile ("MOV\t%0," #Reg "\t/* (*TBI_GETREG OK) */" : \
837 "=r" (__GRValue) ); \
840 #define TBI_SETREG( Reg, Value ) do {\
841 int __SRValue = Value; \
842 __asm__ volatile ("MOV\t" #Reg ",%0\t/* (*TBI_SETREG OK) */" : \
843 : "r" (__SRValue) ); } while (0)
845 #define TBI_SWAPREG( Reg, Value ) do {\
846 int __XRValue = (Value); \
847 __asm__ volatile ("SWAP\t" #Reg ",%0\t/* (*TBI_SWAPREG OK) */" : \
848 "=r" (__XRValue) : "0" (__XRValue) ); \
849 Value = __XRValue; } while (0)
851 /* Obtain and/or release global critical section lock given that interrupts
852 are already disabled and/or should remain disabled. */
853 #define TBI_NOINTSCRITON do {\
854 __asm__ volatile ("LOCK1\t\t/* (*TBI_NOINTSCRITON OK) */");} while (0)
855 #define TBI_NOINTSCRITOFF do {\
856 __asm__ volatile ("LOCK0\t\t/* (*TBI_NOINTSCRITOFF OK) */");} while (0)
857 /* Optimised in-lining versions of the above macros */
859 #define TBI_LOCK( TrigState ) do {\
861 int __ALOCKHI = LINSYSEVENT_WR_ATOMIC_LOCK & 0xFFFF0000; \
862 __asm__ volatile ("MOV %0,#0\t\t/* (*TBI_LOCK ... */\n\t" \
863 "SWAP\t%0,TXMASKI\t/* ... */\n\t" \
864 "LOCK2\t\t/* ... */\n\t" \
865 "SETD\t[%1+#0x40],D1RtP /* ... OK) */" : \
866 "=r&" (__TRValue) : "u" (__ALOCKHI) ); \
867 TrigState = __TRValue; } while (0)
868 #define TBI_CRITON( TrigState ) do {\
870 __asm__ volatile ("MOV %0,#0\t\t/* (*TBI_CRITON ... */\n\t" \
871 "SWAP\t%0,TXMASKI\t/* ... */\n\t" \
872 "LOCK1\t\t/* ... OK) */" : \
873 "=r" (__TRValue) ); \
874 TrigState = __TRValue; } while (0)
876 #define TBI_INTSX( TrigState ) do {\
877 int __TRValue = TrigState; \
878 __asm__ volatile ("SWAP\t%0,TXMASKI\t/* (*TBI_INTSX OK) */" : \
879 "=r" (__TRValue) : "0" (__TRValue) ); \
880 TrigState = __TRValue; } while (0)
882 #define TBI_UNLOCK( TrigState ) do {\
883 int __TRValue = TrigState; \
884 int __ALOCKHI = LINSYSEVENT_WR_ATOMIC_LOCK & 0xFFFF0000; \
885 __asm__ volatile ("SETD\t[%1+#0x00],D1RtP\t/* (*TBI_UNLOCK ... */\n\t" \
886 "LOCK0\t\t/* ... */\n\t" \
887 "MOV\tTXMASKI,%0\t/* ... OK) */" : \
888 : "r" (__TRValue), "u" (__ALOCKHI) ); } while (0)
890 #define TBI_CRITOFF( TrigState ) do {\
891 int __TRValue = TrigState; \
892 __asm__ volatile ("LOCK0\t\t/* (*TBI_CRITOFF ... */\n\t" \
893 "MOV\tTXMASKI,%0\t/* ... OK) */" : \
894 : "r" (__TRValue) ); } while (0)
896 #define TBI_TRIGSX( SrcDst ) do { TBI_SWAPREG( TXMASK, SrcDst );} while (0)
898 /* Composite macros to perform logic ops on INTS or TRIGS masks */
899 #define TBI_INTSOR( Bits ) do {\
900 int __TT = 0; TBI_INTSX(__TT); \
901 __TT |= (Bits); TBI_INTSX(__TT); } while (0)
903 #define TBI_INTSAND( Bits ) do {\
904 int __TT = 0; TBI_INTSX(__TT); \
905 __TT &= (Bits); TBI_INTSX(__TT); } while (0)
908 #define TBI_DEFRICTRLSOR( Bits ) do {\
909 int __TT = TBI_GETREG( CT.20 ); \
910 __TT |= (Bits); TBI_SETREG( CT.20, __TT); } while (0)
912 #define TBI_DEFRICTRLSAND( Bits ) do {\
913 int __TT = TBI_GETREG( TXDEFR ); \
914 __TT &= (Bits); TBI_SETREG( CT.20, __TT); } while (0)
917 #define TBI_TRIGSOR( Bits ) do {\
918 int __TT = TBI_GETREG( TXMASK ); \
919 __TT |= (Bits); TBI_SETREG( TXMASK, __TT); } while (0)
921 #define TBI_TRIGSAND( Bits ) do {\
922 int __TT = TBI_GETREG( TXMASK ); \
923 __TT &= (Bits); TBI_SETREG( TXMASK, __TT); } while (0)
925 /* Macros to disable and re-enable interrupts using TBI_INTSX, deliberate
926 traps and exceptions can still be handled within the critical section. */
927 #define TBI_STOPINTS( Value ) do {\
928 int __TT = TBI_GETREG( TXMASKI ); \
929 __TT &= TXSTATI_BGNDHALT_BIT; TBI_INTSX( __TT ); \
930 Value = __TT; } while (0)
931 #define TBI_RESTINTS( Value ) do {\
932 int __TT = Value; TBI_INTSX( __TT ); } while (0)
934 /* Return pointer to segment list at current privilege level */
935 PTBISEG __TBISegList( void );
937 /* Search the segment list for a match given Id, pStart can be NULL */
938 PTBISEG __TBIFindSeg( PTBISEG pStart, int Id );
940 /* Prepare a new segment structure using space from within another */
941 PTBISEG __TBINewSeg( PTBISEG pFromSeg, int Id, unsigned int Bytes );
943 /* Prepare a new segment using any global or local heap segments available */
944 PTBISEG __TBIMakeNewSeg( int Id, unsigned int Bytes );
946 /* Insert a new segment into the segment list so __TBIFindSeg can locate it */
947 void __TBIAddSeg( PTBISEG pSeg );
948 #define __TBIADDSEG_DEF /* Some versions failed to define this */
950 /* Return Id of current thread; TBID_ISTAT_BIT+TBID_THREAD_BITS */
951 int __TBIThreadId( void );
953 /* Return TBIRES.Thrd data for current thread */
954 TBIRES __TBIThrdPrivId( void );
956 /* Return pointer to current threads TBI root block.
957 Id implies whether Int or Background root block is required */
958 PTBI __TBI( int Id );
960 /* Try to set Mask bit using the spin-lock protocol, return 0 if fails and
961 new state if succeeds */
962 int __TBIPoll( PTBISPIN pLock, int Mask );
964 /* Set Mask bits via the spin-lock protocol in *pLock, return new state */
965 int __TBISpin( PTBISPIN pLock, int Mask );
967 /* Default handler set up for all TBI.fnSigs entries during initialisation */
968 TBIRES __TBIUnExpXXX( TBIRES State, int SigNum,
969 int Triggers, int Inst, PTBI pTBI );
971 /* Call this routine to service triggers at background processing level. The
972 TBID_POLL_BIT of the Id parameter value will be used to indicate that the
973 routine should return if no triggers need to be serviced initially. If this
974 bit is not set the routine will block until one trigger handler is serviced
975 and then behave like the poll case servicing any remaining triggers
976 actually outstanding before returning. Normally the State parameter should
977 be simply initialised to zero and the result should be ignored, other
978 values/options are for internal use only. */
979 TBIRES __TBISyncTrigger( TBIRES State, int Id );
981 /* Call this routine to enable processing of triggers by signal handlers at
982 interrupt level. The State parameter value passed is returned by this
983 routine. The State.Sig.TrigMask field also specifies the initial
984 state of the interrupt mask register TXMASKI to be setup by the call.
985 The other parts of the State parameter are ignored unless the PRIV bit is
986 set in the SaveMask field. In this case the State.Sig.pCtx field specifies
987 the base of the stack to which the interrupt system should switch into
988 as it saves the state of the previously executing code. In the case the
989 thread will be unprivileged as it continues execution at the return
990 point of this routine and it's future state will be effectively never
991 trusted to be valid. */
992 TBIRES __TBIASyncTrigger( TBIRES State );
994 /* Call this to swap soft threads executing at the background processing level.
995 The TBIRES returned to the new thread will be the same as the NextThread
996 value specified to the call. The NextThread.Switch.pCtx value specifies
997 which thread context to restore and the NextThread.Switch.Para value can
998 hold an arbitrary expression to be passed between the threads. The saved
999 state of the previous thread will be stored in a TBICTX descriptor created
1000 on it's stack and the address of this will be stored into the *rpSaveCtx
1001 location specified. */
1002 TBIRES __TBISwitch( TBIRES NextThread, PTBICTX *rpSaveCtx );
1004 /* Call this to initialise a stack frame ready for further use, up to four
1005 32-bit arguments may be specified after the fixed args to be passed via
1006 the new stack pStack to the routine specified via fnMain. If the
1007 main-line routine ever returns the thread will operate as if main itself
1008 had returned and terminate with the return code given. */
1009 typedef int (*PTBIMAINFN)( TBIRES Arg /*, <= 4 additional 32-bit args */ );
1010 PTBICTX __TBISwitchInit( void *pStack, PTBIMAINFN fnMain, ... );
1012 /* Call this to resume a thread from a saved synchronous TBICTX state.
1013 The TBIRES returned to the new thread will be the same as the NextThread
1014 value specified to the call. The NextThread.Switch.pCtx value specifies
1015 which thread context to restore and the NextThread.Switch.Para value can
1016 hold an arbitrary expression to be passed between the threads. The context
1017 of the calling thread is lost and this routine never returns to the
1018 caller. The TrigsMask value supplied is ored into TXMASKI to enable
1019 interrupts after the context of the new thread is established. */
1020 void __TBISyncResume( TBIRES NextThread, int TrigsMask );
1022 /* Call these routines to save and restore the extended states of
1024 void *__TBICtxSave( TBIRES State, void *pExt );
1025 void *__TBICtxRestore( TBIRES State, void *pExt );
1028 #ifdef TBI_FASTINT_1_4
1029 /* Call these routines to copy the GP state to a separate buffer
1030 * Only necessary for context switching.
1032 PTBICTXGP __TBICtx2SaveCrit( PTBICTX2 pCurrentCtx, PTBICTX2 pSaveCtx );
1033 void *__TBICtx2SaveGP( PTBICTXGP pCurrentCtxGP, PTBICTXGP pSaveCtxGP );
1035 /* Call these routines to save and restore the extended states of
1037 void *__TBICtx2Save( PTBICTXGP pCtxGP, short SaveMask, void *pExt );
1038 void *__TBICtx2Restore( PTBICTX2 pCtx, short SaveMask, void *pExt );
1041 /* If FPAC flag is set then significant FPU context exists. Call these routine
1042 to save and restore it */
1043 void *__TBICtxFPUSave( TBIRES State, void *pExt );
1044 void *__TBICtxFPURestore( TBIRES State, void *pExt );
1046 #ifdef TBI_FASTINT_1_4
1047 extern void *__TBICtx2FPUSave (PTBICTXGP, short, void*);
1048 extern void *__TBICtx2FPURestore (PTBICTXGP, short, void*);
1053 /* Call these routines to save and restore DSPRAM. */
1054 void *__TBIDspramSaveA (short DspramSizes, void *pExt);
1055 void *__TBIDspramSaveB (short DspramSizes, void *pExt);
1056 void *__TBIDspramRestoreA (short DspramSizes, void *pExt);
1057 void *__TBIDspramRestoreB (short DspramSizes, void *pExt);
1060 /* This routine should be used at the entrypoint of interrupt handlers to
1061 re-enable higher priority interrupts and/or save state from the previously
1062 executing background code. State is a TBIRES.Sig parameter with NoNestMask
1063 indicating the triggers (if any) that should remain disabled and SaveMask
1064 CBUF bit indicating the if the hardware catch buffer is dirty. Optionally
1065 any number of extended state bits X??? including XCBF can be specified to
1066 force a nested state save call to __TBICtxSave before the current routine
1067 continues. (In the latter case __TBICtxRestore should be called to restore
1068 any extended states before the background thread of execution is resumed)
1070 By default (no X??? bits specified in SaveMask) this routine performs a
1071 sub-call to __TBICtxSave with the pExt and State parameters specified IF
1072 some triggers could be serviced while the current interrupt handler
1073 executes and the hardware catch buffer is actually dirty. In this case
1074 this routine provides the XCBF bit in State.Sig.SaveMask to force the
1075 __TBICtxSave to extract the current catch state.
1077 The NoNestMask parameter should normally indicate that the same or lower
1078 triggers than those provoking the current handler call should not be
1079 serviced in nested calls, zero may be specified if all possible interrupts
1082 The TBIRES.Sig value returned will be similar to the State parameter
1083 specified with the XCBF bit ORed into it's SaveMask if a context save was
1084 required and fewer bits set in it's TrigMask corresponding to the same/lower
1085 priority interrupt triggers still not enabled. */
1086 TBIRES __TBINestInts( TBIRES State, void *pExt, int NoNestMask );
1088 /* This routine causes the TBICTX structure specified in State.Sig.pCtx to
1089 be restored. This implies that execution will not return to the caller.
1090 The State.Sig.TrigMask field will be restored during the context switch
1091 such that any immediately occuring interrupts occur in the context of the
1092 newly specified task. The State.Sig.SaveMask parameter is ignored. */
1093 void __TBIASyncResume( TBIRES State );
1095 /* Call this routine to enable fastest possible processing of one or more
1096 interrupt triggers via a unified signal handler. The handler concerned
1097 must simple return after servicing the related hardware.
1098 The State.Sig.TrigMask parameter indicates the interrupt triggers to be
1099 enabled and the Thin.Thin.fnHandler specifies the routine to call and
1100 the whole Thin parameter value will be passed to this routine unaltered as
1101 it's first parameter. */
1102 void __TBIASyncThin( TBIRES State, TBIRES Thin );
1104 /* Do this before performing your own direct spin-lock access - use TBI_LOCK */
1105 int __TBILock( void );
1107 /* Do this after performing your own direct spin-lock access - use TBI_UNLOCK */
1108 void __TBIUnlock( int TrigState );
1110 /* Obtain and release global critical section lock - only stops execution
1111 of interrupts on this thread and similar critical section code on other
1112 local threads - use TBI_CRITON or TBI_CRITOFF */
1113 int __TBICritOn( void );
1114 void __TBICritOff( int TrigState );
1116 /* Change INTS (TXMASKI) - return old state - use TBI_INTSX */
1117 int __TBIIntsX( int NewMask );
1119 /* Change TRIGS (TXMASK) - return old state - use TBI_TRIGSX */
1120 int __TBITrigsX( int NewMask );
1122 /* This function initialises a timer for first use, only the TBID_ISTAT_BIT
1123 of the Id parameter is used to indicate which timer is to be modified. The
1124 Wait value should either be zero to disable the timer concerned or be in
1125 the recommended TBI_TIMERWAIT_* range to specify the delay required before
1126 the first timer trigger occurs.
1128 The TBID_ISTAT_BIT of the Id parameter similar effects all other timer
1129 support functions (see below). */
1130 void __TBITimerCtrl( int Id, int Wait );
1132 /* This routine returns a 64-bit time stamp value that is initialised to zero
1133 via a __TBITimerCtrl timer enabling call. */
1134 long long __TBITimeStamp( int Id );
1136 /* To manage a periodic timer each period elapsed should be subracted from
1137 the current timer value to attempt to set up the next timer trigger. The
1138 Wait parameter should be a value in the recommended TBI_TIMERWAIT_* range.
1139 The return value is the new aggregate value that the timer was updated to,
1140 if this is less than zero then a timer trigger is guaranteed to be
1141 generated after the number of ticks implied, if a positive result is
1142 returned either itterative or step-wise corrective action must be taken to
1143 resynchronise the timer and hence provoke a future timer trigger. */
1144 int __TBITimerAdd( int Id, int Wait );
1146 /* String table search function, pStart is first entry to check or NULL,
1147 pStr is string data to search for and MatchLen is either length of string
1148 to compare for an exact match or negative length to compare for partial
1150 const TBISTR *__TBIFindStr( const TBISTR *pStart,
1151 const char *pStr, int MatchLen );
1153 /* String table translate function, pStr is text to translate and Len is
1154 it's length. Value returned may not be a string pointer if the
1155 translation value is really some other type, 64-bit alignment of the return
1156 pointer is guaranteed so almost any type including a structure could be
1157 located with this routine. */
1158 const void *__TBITransStr( const char *pStr, int Len );
1162 /* Arbitrary physical memory access windows, use different Channels to avoid
1163 conflict/thrashing within a single piece of code. */
1164 void *__TBIPhysAccess( int Channel, int PhysAddr, int Bytes );
1165 void __TBIPhysRelease( int Channel, void *pLinAddr );
1168 /* Data cache function nullified because data cache is off */
1169 #define TBIDCACHE_FLUSH( pAddr )
1170 #define TBIDCACHE_PRELOAD( Type, pAddr ) ((Type) (pAddr))
1171 #define TBIDCACHE_REFRESH( Type, pAddr ) ((Type) (pAddr))
1174 /* To flush a single cache line from the data cache using a linear address */
1175 #define TBIDCACHE_FLUSH( pAddr ) ((volatile char *) \
1176 (((unsigned int) (pAddr))>>LINSYSLFLUSH_S))[0] = 0
1178 extern void * __builtin_dcache_preload (void *);
1180 /* Try to ensure that the data at the address concerned is in the cache */
1181 #define TBIDCACHE_PRELOAD( Type, Addr ) \
1182 ((Type) __builtin_dcache_preload ((void *)(Addr)))
1184 extern void * __builtin_dcache_refresh (void *);
1186 /* Flush any old version of data from address and re-load a new copy */
1187 #define TBIDCACHE_REFRESH( Type, Addr ) __extension__ ({ \
1188 Type __addr = (Type)(Addr); \
1189 (void)__builtin_dcache_refresh ((void *)(((unsigned int)(__addr))>>6)); \
1195 /* Support for DCACHE builtin */
1196 extern void __builtin_dcache_flush (void *);
1198 /* To flush a single cache line from the data cache using a linear address */
1199 #define TBIDCACHE_FLUSH( Addr ) \
1200 __builtin_dcache_flush ((void *)(Addr))
1202 extern void * __builtin_dcache_preload (void *);
1204 /* Try to ensure that the data at the address concerned is in the cache */
1205 #define TBIDCACHE_PRELOAD( Type, Addr ) \
1206 ((Type) __builtin_dcache_preload ((void *)(Addr)))
1208 extern void * __builtin_dcache_refresh (void *);
1210 /* Flush any old version of data from address and re-load a new copy */
1211 #define TBIDCACHE_REFRESH( Type, Addr ) \
1212 ((Type) __builtin_dcache_refresh ((void *)(Addr)))
1217 /* Flush the MMCU cache */
1218 #define TBIMCACHE_FLUSH() { ((volatile int *) LINSYSCFLUSH_MMCU)[0] = 0; }
1221 /* Obtain the MMU table entry for the specified address */
1222 #define TBIMTABLE_LEAFDATA(ADDR) TBIXCACHE_RD((int)(ADDR) & (-1<<6))
1224 #ifndef __ASSEMBLY__
1225 /* Obtain the full MMU table entry for the specified address */
1226 #define TBIMTABLE_DATA(ADDR) __extension__ ({ TBIRES __p; \
1227 __p.Val = TBIXCACHE_RL((int)(ADDR) & (-1<<6)); \
1232 /* Combine a physical base address, and a linear address
1235 #define _TBIMTABLE_LIN2PHYS(PHYS, LIN, LMASK) (void*)(((int)(PHYS)&0xFFFFF000)\
1236 +((int)(LIN)&(LMASK)))
1238 /* Convert a linear to a physical address */
1239 #define TBIMTABLE_LIN2PHYS(LEAFDATA, ADDR) \
1240 (((LEAFDATA) & CRLINPHY0_VAL_BIT) \
1241 ? _TBIMTABLE_LIN2PHYS(LEAFDATA, ADDR, 0x00000FFF) \
1244 /* Debug support - using external debugger or host */
1245 void __TBIDumpSegListEntries( void );
1246 void __TBILogF( const char *pFmt, ... );
1247 void __TBIAssert( const char *pFile, int LineNum, const char *pExp );
1248 void __TBICont( const char *pMsg, ... ); /* TBIAssert -> 'wait for continue' */
1250 /* Array of signal name data for debug messages */
1251 extern const char __TBISigNames[];
1252 #endif /* ifndef __ASSEMBLY__ */
1256 /* Scale of sub-strings in the __TBISigNames string list */
1257 #define TBI_SIGNAME_SCALE 4
1258 #define TBI_SIGNAME_SCALE_S 2
1264 #ifndef __ASSEMBLY__
1265 #define TBIXCACHE_RD(ADDR) __extension__ ({\
1266 void * __Addr = (void *)(ADDR); \
1268 __asm__ volatile ( "CACHERD\t%0,[%1+#0]" : \
1269 "=r" (__Data) : "r" (__Addr) ); \
1272 #define TBIXCACHE_RL(ADDR) __extension__ ({\
1273 void * __Addr = (void *)(ADDR); \
1275 __asm__ volatile ( "CACHERL\t%0,%t0,[%1+#0]" : \
1276 "=d" (__Data) : "r" (__Addr) ); \
1279 #define TBIXCACHE_WD(ADDR, DATA) do {\
1280 void * __Addr = (void *)(ADDR); \
1281 int __Data = DATA; \
1282 __asm__ volatile ( "CACHEWD\t[%0+#0],%1" : \
1283 : "r" (__Addr), "r" (__Data) ); } while(0)
1285 #define TBIXCACHE_WL(ADDR, DATA) do {\
1286 void * __Addr = (void *)(ADDR); \
1287 long long __Data = DATA; \
1288 __asm__ volatile ( "CACHEWL\t[%0+#0],%1,%t1" : \
1289 : "r" (__Addr), "r" (__Data) ); } while(0)
1293 #define TBICACHE_FLUSH_L1D_L2(ADDR) \
1294 TBIXCACHE_WD(ADDR, CACHEW_FLUSH_L1D_L2)
1295 #define TBICACHE_WRITEBACK_L1D_L2(ADDR) \
1296 TBIXCACHE_WD(ADDR, CACHEW_WRITEBACK_L1D_L2)
1297 #define TBICACHE_INVALIDATE_L1D(ADDR) \
1298 TBIXCACHE_WD(ADDR, CACHEW_INVALIDATE_L1D)
1299 #define TBICACHE_INVALIDATE_L1D_L2(ADDR) \
1300 TBIXCACHE_WD(ADDR, CACHEW_INVALIDATE_L1D_L2)
1301 #define TBICACHE_INVALIDATE_L1DTLB(ADDR) \
1302 TBIXCACHE_WD(ADDR, CACHEW_INVALIDATE_L1DTLB)
1303 #define TBICACHE_INVALIDATE_L1I(ADDR) \
1304 TBIXCACHE_WD(ADDR, CACHEW_INVALIDATE_L1I)
1305 #define TBICACHE_INVALIDATE_L1ITLB(ADDR) \
1306 TBIXCACHE_WD(ADDR, CACHEW_INVALIDATE_L1ITLB)
1308 #endif /* TBI_4_0 */
1309 #endif /* ifndef __ASSEMBLY__ */
1312 * Calculate linear PC value from real PC and Minim mode control, the LSB of
1313 * the result returned indicates if address compression has occured.
1315 #ifndef __ASSEMBLY__
1316 #define METAG_LINPC( PCVal ) (\
1317 ( (TBI_GETREG(TXPRIVEXT) & TXPRIVEXT_MINIMON_BIT) != 0 ) ? ( \
1318 ( ((PCVal) & 0x00900000) == 0x00900000 ) ? \
1319 (((PCVal) & 0xFFE00000) + (((PCVal) & 0x001FFFFC)>>1) + 1) : \
1320 ( ((PCVal) & 0x00800000) == 0x00000000 ) ? \
1321 (((PCVal) & 0xFF800000) + (((PCVal) & 0x007FFFFC)>>1) + 1) : \
1324 #define METAG_LINPC_X2BIT 0x00000001 /* Make (Size>>1) if compressed */
1326 /* Convert an arbitrary Linear address into a valid Minim PC or return 0 */
1327 #define METAG_PCMINIM( LinVal ) (\
1328 (((LinVal) & 0x00980000) == 0x00880000) ? \
1329 (((LinVal) & 0xFFE00000) + (((LinVal) & 0x000FFFFE)<<1)) : \
1330 (((LinVal) & 0x00C00000) == 0x00000000) ? \
1331 (((LinVal) & 0xFF800000) + (((LinVal) & 0x003FFFFE)<<1)) : 0 )
1333 /* Reverse a METAG_LINPC conversion step to return the original PCVal */
1334 #define METAG_PCLIN( LinVal ) ( 0xFFFFFFFC & (\
1335 ( (LinVal & METAG_LINPC_X2BIT) != 0 ) ? METAG_PCMINIM( LinVal ) : \
1339 * Flush the MMCU Table cache privately for each thread. On cores that do not
1340 * support per-thread flushing it will flush all threads mapping data.
1342 #define TBIMCACHE_TFLUSH(Thread) do {\
1343 ((volatile int *)( LINSYSCFLUSH_TxMMCU_BASE + \
1344 (LINSYSCFLUSH_TxMMCU_STRIDE*(Thread)) ))[0] = 0; \
1348 * To flush a single linear-matched cache line from the code cache. In
1349 * cases where Minim is possible the METAC_LINPC operation must be used
1350 * to pre-process the address being flushed.
1352 #define TBIICACHE_FLUSH( pAddr ) TBIXCACHE_WD (pAddr, CACHEW_ICACHE_BIT)
1354 /* To flush a single linear-matched mapping from code/data MMU table cache */
1355 #define TBIMCACHE_AFLUSH( pAddr, SegType ) \
1356 TBIXCACHE_WD(pAddr, CACHEW_TLBFLUSH_BIT + ( \
1357 ((SegType) == TBID_SEGTYPE_TEXT) ? CACHEW_ICACHE_BIT : 0 ))
1360 * To flush translation data corresponding to a range of addresses without
1361 * using TBITCACHE_FLUSH to flush all of this threads translation data. It
1362 * is necessary to know what stride (>= 4K) must be used to flush a specific
1365 * For example direct mapped regions use the maximum page size (512K) which may
1366 * mean that only one flush is needed to cover the sub-set of the direct
1367 * mapped area used since it was setup.
1369 * The function returns the stride on which flushes should be performed.
1371 * If 0 is returned then the region is not subject to MMU caching, if -1 is
1372 * returned then this indicates that only TBIMCACHE_TFLUSH can be used to
1373 * flush the region concerned rather than TBIMCACHE_AFLUSH which this
1374 * function is designed to support.
1376 int __TBIMMUCacheStride( const void *pStart, int Bytes );
1379 * This function will use the above lower level functions to achieve a MMU
1380 * table data flush in an optimal a fashion as possible. On a system that
1381 * supports linear address based caching this function will also call the
1382 * code or data cache flush functions to maintain address/data coherency.
1384 * SegType should be TBID_SEGTYPE_TEXT if the address range is for code or
1385 * any other value such as TBID_SEGTYPE_DATA for data. If an area is
1386 * used in both ways then call this function twice; once for each.
1388 void __TBIMMUCacheFlush( const void *pStart, int Bytes, int SegType );
1391 * Cached Core mode setup and flush functions allow one code and one data
1392 * region of the corresponding global or local cache partion size to be
1393 * locked into the corresponding cache memory. This prevents normal LRU
1394 * logic discarding the code or data and avoids write-thru bandwidth in
1395 * data areas. Code mappings are selected by specifying TBID_SEGTYPE_TEXT
1396 * for SegType, otherwise data mappings are created.
1398 * Mode supplied should always contain the VALID bit and WINx selection data.
1399 * Data areas will be mapped read-only if the WRITE bit is not added.
1401 * The address returned by the Opt function will either be the same as that
1402 * passed in (if optimisation cannot be supported) or the base of the new core
1403 * cached region in linear address space. The returned address must be passed
1404 * into the End function to remove the mapping when required. If a non-core
1405 * cached memory address is passed into it the End function has no effect.
1406 * Note that the region accessed MUST be flushed from the appropriate cache
1407 * before the End function is called to deliver correct operation.
1409 void *__TBICoreCacheOpt( const void *pStart, int Bytes, int SegType, int Mode );
1410 void __TBICoreCacheEnd( const void *pOpt, int Bytes, int SegType );
1413 * Optimise physical access channel and flush side effects before releasing
1414 * the channel. If pStart is NULL the whole region must be flushed and this is
1415 * done automatically by the channel release function if optimisation is
1416 * enabled. Flushing the specific region that may have been accessed before
1417 * release should optimises this process. On physically cached systems we do
1418 * not flush the code/data caches only the MMU table data needs flushing.
1420 void __TBIPhysOptim( int Channel, int IMode, int DMode );
1421 void __TBIPhysFlush( int Channel, const void *pStart, int Bytes );
1423 #endif /* ifdef TBI_1_3 */
1425 #endif /* _ASM_METAG_TBX_H_ */