graphics.library: MakeVPort() RastInfo based double-buffering fixes
[AROS.git] / rom / exec / exec_init.c
blob34b315f258c86cbf6f1bad02c9bfacae6d2b074e
1 /*
2 Copyright © 1995-2012, The AROS Development Team. All rights reserved.
3 $Id$
5 Desc: exec.library resident and initialization.
6 Lang: english
7 */
9 #include <exec/lists.h>
10 #include <exec/execbase.h>
11 #include <exec/interrupts.h>
12 #include <exec/resident.h>
13 #include <exec/memory.h>
14 #include <exec/alerts.h>
15 #include <exec/tasks.h>
16 #include <hardware/intbits.h>
18 #include <aros/symbolsets.h>
19 #include <aros/system.h>
20 #include <aros/arossupportbase.h>
21 #include <aros/asmcall.h>
22 #include <aros/config.h>
24 #include <aros/debug.h>
26 #include <proto/arossupport.h>
27 #include <proto/exec.h>
28 #include <proto/kernel.h>
30 #include "exec_debug.h"
31 #include "exec_intern.h"
32 #include "exec_util.h"
33 #include "etask.h"
34 #include "intservers.h"
35 #include "memory.h"
36 #include "taskstorage.h"
38 #include LC_LIBDEFS_FILE
40 static const UBYTE name[];
41 static const UBYTE version[];
43 /* This comes from genmodule */
44 extern const char LIBEND;
46 AROS_UFP3S(struct ExecBase *, GM_UNIQUENAME(init),
47 AROS_UFPA(struct MemHeader *, mh, D0),
48 AROS_UFPA(struct TagItem *, tagList, A0),
49 AROS_UFPA(struct ExecBase *, sysBase, A6));
52 * exec.library ROMTag.
54 * It has RTF_COLDSTART level specified, however it actually runs at SINGLETASK
55 * (no multitasking, incomplete boot task).
56 * This is supposed to be the first COLDSTART resident to be executed. Its job is
57 * to complete the boot task and enable multitasking (which actually means entering
58 * COLDSTART level).
59 * Such mechanism allows kernel.resource boot code to do some additional setup after
60 * all SINGLETASK residents are run. Usually these are various lowlevel hardware resources
61 * (like acpi.resource, efi.resource, etc) which can be needed for kernel.resource to
62 * complete own setup. This helps to get rid of additional ROMTag hooks.
63 * There's one more magic with this ROMTag: it's called twice. First time it's called manually
64 * from within krnPrepareExecBase(), for initial ExecBase creation. This magic is described below.
66 * WARNING: the CPU privilege level must be set to user before calling InitCode(RTF_COLDSTART)!
68 const struct Resident Exec_resident =
70 RTC_MATCHWORD,
71 (struct Resident *)&Exec_resident,
72 (APTR)&LIBEND,
73 RTF_COLDSTART,
74 VERSION_NUMBER,
75 NT_LIBRARY,
76 120,
77 (STRPTR)name,
78 (STRPTR)&version[6],
79 &GM_UNIQUENAME(init),
82 static const UBYTE name[] = MOD_NAME_STRING;
83 static const UBYTE version[] = VERSION_STRING;
85 extern void debugmem(void);
87 void SupervisorAlertTask(struct ExecBase *SysBase);
89 THIS_PROGRAM_HANDLES_SYMBOLSET(INITLIB)
90 THIS_PROGRAM_HANDLES_SYMBOLSET(PREINITLIB)
91 DEFINESET(INITLIB)
92 DEFINESET(PREINITLIB)
94 AROS_UFH3S(struct ExecBase *, GM_UNIQUENAME(init),
95 AROS_UFHA(struct MemHeader *, mh, D0),
96 AROS_UFHA(struct TagItem *, tagList, A0),
97 AROS_UFHA(struct ExecBase *, origSysBase, A6)
100 AROS_USERFUNC_INIT
102 struct TaskStorageFreeSlot *tsfs;
103 struct Task *t;
104 struct MemList *ml;
105 struct ExceptionContext *ctx;
106 int i;
109 * exec.library init routine is a little bit magic. The magic is that it
110 * can be run twice.
111 * First time it's run manually from kernel.resource's ROMTag scanner in order
112 * to create initial ExecBase. This condition is determined by origSysBase == NULL
113 * passed to this function. In this case the routine expects two more arguments:
114 * mh - an initial MemHeader in which ExecBase will be constructed.
115 * tagList - boot information passed from the bootstrap. It is used to parse
116 * certain command-line arguments.
118 * Second time it's run as part of normal modules initialization sequence, at the
119 * end of all RTS_SINGLETASK modules. At this moment we already have a complete
120 * memory list and working kernel.resource. Now the job is to complete the boot task
121 * structure, and start up multitasking.
123 if (!origSysBase)
124 return PrepareExecBase(mh, tagList);
126 DINIT("exec.library init");
129 * Call platform-specific pre-init code (if any). Return values are not checked.
130 * Note that Boot Task is still incomplete here, and there's no multitasking yet.
132 * TODO: Amiga(tm) port may call PrepareExecBaseMove() here instead of hardlinking
133 * it from within the boot code.
135 * NOTE: All functions will be passed origSysBase value. This is the original
136 * ExecBase pointer in case if it was moved. The new pointer will be in global
137 * SysBase then.
139 set_call_libfuncs(SETNAME(PREINITLIB), 1, 0, origSysBase);
142 * kernel.resource is up and running and memory list is complete.
143 * Global SysBase is set to its final value. We've got KernelBase and AllocMem() works.
144 * Initialize free task storage slots management
146 tsfs = AllocMem(sizeof(struct TaskStorageFreeSlot), MEMF_PUBLIC|MEMF_CLEAR);
147 if (!tsfs)
149 DINIT("ERROR: Could not allocate free slot node!");
150 return NULL;
152 tsfs->FreeSlot = __TS_FIRSTSLOT+1;
153 AddHead((struct List *)&PrivExecBase(SysBase)->TaskStorageSlots, (struct Node *)tsfs);
155 /* Now we are ready to become a Boot Task and turn on the multitasking */
156 t = AllocMem(sizeof(struct Task), MEMF_PUBLIC|MEMF_CLEAR);
157 ml = AllocMem(sizeof(struct MemList), MEMF_PUBLIC|MEMF_CLEAR);
158 ctx = KrnCreateContext();
160 if (!t || !ml || !ctx)
162 DINIT("Not enough memory for first task");
163 return NULL;
166 NEWLIST(&t->tc_MemEntry);
168 t->tc_Node.ln_Name = "Boot Task";
169 t->tc_Node.ln_Type = NT_TASK;
170 t->tc_Node.ln_Pri = 0;
171 t->tc_State = TS_RUN;
172 t->tc_SigAlloc = 0xFFFF;
175 * Boot-time stack can be placed anywhere in memory.
176 * In order to avoid complex platform-dependent mechanism for querying its limits
177 * we simply shut up stack checking in kernel.resource by specifying the whole address
178 * space as limits.
180 t->tc_SPLower = NULL;
181 t->tc_SPUpper = (APTR)~0;
184 * Build a memory list for the task.
185 * It doesn't include stack because it wasn't allocated by us.
187 ml->ml_NumEntries = 1;
188 ml->ml_ME[0].me_Addr = t;
189 ml->ml_ME[0].me_Length = sizeof(struct Task);
190 AddHead(&t->tc_MemEntry, &ml->ml_Node);
192 /* Create a ETask structure and attach CPU context */
193 if (!InitETask(t))
195 DINIT("Not enough memory for first task");
196 return NULL;
198 t->tc_UnionETask.tc_ETask->et_RegFrame = ctx;
200 DINIT("[exec] Boot Task 0x%p, ETask 0x%p, CPU context 0x%p\n", t, t->tc_UnionETask.tc_ETask, ctx);
203 * Set the current task and elapsed time for it.
204 * Set ThisTask only AFTER InitETask() has been called. InitETask() sets et_Parent
205 * to FindTask(NULL). We must get NULL there, otherwise we'll get task looped on itself.
207 SysBase->ThisTask = t;
208 SysBase->Elapsed = SysBase->Quantum;
210 /* Install the interrupt servers. Again, do it here because allocations are needed. */
211 for (i=0; i < 16; i++)
213 struct Interrupt *is;
215 if (i != INTB_SOFTINT)
217 struct SoftIntList *sil;
219 is = AllocMem(sizeof(struct Interrupt) + sizeof(struct SoftIntList), MEMF_CLEAR|MEMF_PUBLIC);
220 if (is == NULL)
222 DINIT("ERROR: Cannot install Interrupt Servers!");
223 Alert( AT_DeadEnd | AN_IntrMem );
226 sil = (struct SoftIntList *)((struct Interrupt *)is + 1);
228 if (i == INTB_VERTB)
229 is->is_Code = (VOID_FUNC)VBlankServer;
230 else
231 is->is_Code = (VOID_FUNC)IntServer;
232 is->is_Data = sil;
233 NEWLIST((struct List *)sil);
234 SetIntVector(i,is);
236 else
238 struct Interrupt * is;
240 is = AllocMem(sizeof(struct Interrupt), MEMF_CLEAR|MEMF_PUBLIC);
241 if (NULL == is)
243 DINIT("Error: Cannot install SoftInt Handler!\n");
244 Alert( AT_DeadEnd | AN_IntrMem );
247 is->is_Node.ln_Type = NT_INTERRUPT;
248 is->is_Node.ln_Pri = 0;
249 is->is_Node.ln_Name = "SW Interrupt Dispatcher";
250 is->is_Data = NULL;
251 is->is_Code = (void *)SoftIntDispatch;
252 SetIntVector(i,is);
256 /* We now start up the interrupts */
257 Permit();
258 Enable();
260 D(debugmem());
262 /* Our housekeeper must have the largest possible priority */
263 t = NewCreateTask(TASKTAG_NAME , "Exec housekeeper",
264 TASKTAG_PRI , 127,
265 TASKTAG_PC , ServiceTask,
266 TASKTAG_TASKMSGPORT, &((struct IntExecBase *)SysBase)->ServicePort,
267 TASKTAG_ARG1 , SysBase,
268 TAG_DONE);
269 if (!t)
271 DINIT("Failed to start up service task");
272 return NULL;
275 /* Create task for handling supervisor level errors */
276 NewCreateTask(TASKTAG_NAME , "Exec Guru Task",
277 TASKTAG_PRI , 126,
278 TASKTAG_PC , SupervisorAlertTask,
279 TASKTAG_ARG1 , SysBase,
280 TAG_DONE);
282 /* Call platform-specific init code (if any) */
283 set_call_libfuncs(SETNAME(INITLIB), 1, 1, SysBase);
285 /* Multitasking is on. Call CoolCapture. */
286 if (SysBase->CoolCapture)
288 DINIT("Calling CoolCapture at 0x%p", SysBase->CoolCapture);
290 AROS_UFC1NR(void, SysBase->CoolCapture,
291 AROS_UFCA(struct Library *, (struct Library *)SysBase, A6));
294 /* Done. Following the convention, we return our base pointer. */
295 return SysBase;
297 AROS_USERFUNC_EXIT
300 AROS_PLH1(struct ExecBase *, open,
301 AROS_LHA(ULONG, version, D0),
302 struct ExecBase *, SysBase, 1, Exec)
304 AROS_LIBFUNC_INIT
306 /* I have one more opener. */
307 SysBase->LibNode.lib_OpenCnt++;
308 return SysBase;
310 AROS_LIBFUNC_EXIT
313 AROS_PLH0(BPTR, close,
314 struct ExecBase *, SysBase, 2, Exec)
316 AROS_LIBFUNC_INIT
318 /* I have one fewer opener. */
319 SysBase->LibNode.lib_OpenCnt--;
320 return 0;
322 AROS_LIBFUNC_EXIT