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1 | /*++\r | |
2 | \r | |
3 | Copyright (c) 2006, Intel Corporation \r | |
4 | All rights reserved. This program and the accompanying materials \r | |
5 | are licensed and made available under the terms and conditions of the BSD License \r | |
6 | which accompanies this distribution. The full text of the license may be found at \r | |
7 | http://opensource.org/licenses/bsd-license.php \r | |
8 | \r | |
9 | THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, \r | |
10 | WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. \r | |
11 | \r | |
12 | Module Name:\r | |
13 | \r | |
14 | EbcSupport.c\r | |
15 | \r | |
16 | Abstract:\r | |
17 | \r | |
18 | This module contains EBC support routines that are customized based on\r | |
19 | the target processor.\r | |
20 | \r | |
21 | --*/\r | |
22 | \r | |
23 | #include "EbcInt.h"\r | |
24 | #include "EbcExecute.h"\r | |
25 | \r | |
26 | //\r | |
27 | // NOTE: This is the stack size allocated for the interpreter\r | |
28 | // when it executes an EBC image. The requirements can change\r | |
29 | // based on whether or not a debugger is present, and other\r | |
30 | // platform-specific configurations.\r | |
31 | //\r | |
32 | #define VM_STACK_SIZE (1024 * 4)\r | |
33 | #define EBC_THUNK_SIZE 32\r | |
34 | \r | |
35 | #define STACK_REMAIN_SIZE (1024 * 4)\r | |
36 | VOID\r | |
37 | EbcLLCALLEX (\r | |
38 | IN VM_CONTEXT *VmPtr,\r | |
39 | IN UINTN FuncAddr,\r | |
40 | IN UINTN NewStackPointer,\r | |
41 | IN VOID *FramePtr,\r | |
42 | IN UINT8 Size\r | |
43 | )\r | |
44 | /*++\r | |
45 | \r | |
46 | Routine Description:\r | |
47 | \r | |
48 | This function is called to execute an EBC CALLEX instruction. \r | |
49 | The function check the callee's content to see whether it is common native\r | |
50 | code or a thunk to another piece of EBC code.\r | |
51 | If the callee is common native code, use EbcLLCAllEXASM to manipulate,\r | |
52 | otherwise, set the VM->IP to target EBC code directly to avoid another VM\r | |
53 | be startup which cost time and stack space.\r | |
54 | \r | |
55 | Arguments:\r | |
56 | \r | |
57 | VmPtr - Pointer to a VM context.\r | |
58 | FuncAddr - Callee's address\r | |
59 | NewStackPointer - New stack pointer after the call\r | |
60 | FramePtr - New frame pointer after the call\r | |
61 | Size - The size of call instruction\r | |
62 | \r | |
63 | Returns:\r | |
64 | \r | |
65 | None.\r | |
66 | \r | |
67 | --*/\r | |
68 | {\r | |
69 | UINTN IsThunk;\r | |
70 | UINTN TargetEbcAddr;\r | |
71 | \r | |
72 | IsThunk = 1;\r | |
73 | TargetEbcAddr = 0;\r | |
74 | \r | |
75 | //\r | |
76 | // Processor specific code to check whether the callee is a thunk to EBC.\r | |
77 | //\r | |
78 | if (*((UINT8 *)FuncAddr) != 0xB8) {\r | |
79 | IsThunk = 0;\r | |
80 | goto Action;\r | |
81 | }\r | |
82 | if (*((UINT8 *)FuncAddr + 1) != 0xBC) {\r | |
83 | IsThunk = 0;\r | |
84 | goto Action;\r | |
85 | }\r | |
86 | if (*((UINT8 *)FuncAddr + 2) != 0x2E) {\r | |
87 | IsThunk = 0;\r | |
88 | goto Action;\r | |
89 | }\r | |
90 | if (*((UINT8 *)FuncAddr + 3) != 0x11) {\r | |
91 | IsThunk = 0;\r | |
92 | goto Action;\r | |
93 | }\r | |
94 | if (*((UINT8 *)FuncAddr + 4) != 0xCA) {\r | |
95 | IsThunk = 0;\r | |
96 | goto Action;\r | |
97 | }\r | |
98 | if (*((UINT8 *)FuncAddr + 5) != 0xB8) {\r | |
99 | IsThunk = 0;\r | |
100 | goto Action;\r | |
101 | }\r | |
102 | if (*((UINT8 *)FuncAddr + 10) != 0xB9) {\r | |
103 | IsThunk = 0;\r | |
104 | goto Action;\r | |
105 | }\r | |
106 | if (*((UINT8 *)FuncAddr + 15) != 0xFF) {\r | |
107 | IsThunk = 0;\r | |
108 | goto Action;\r | |
109 | }\r | |
110 | if (*((UINT8 *)FuncAddr + 16) != 0xE1) {\r | |
111 | IsThunk = 0;\r | |
112 | goto Action;\r | |
113 | }\r | |
114 | \r | |
115 | TargetEbcAddr = ((UINTN)(*((UINT8 *)FuncAddr + 9)) << 24) + ((UINTN)(*((UINT8 *)FuncAddr + 8)) << 16) +\r | |
116 | ((UINTN)(*((UINT8 *)FuncAddr + 7)) << 8) + ((UINTN)(*((UINT8 *)FuncAddr + 6)));\r | |
117 | \r | |
118 | Action:\r | |
119 | if (IsThunk == 1){\r | |
120 | //\r | |
121 | // The callee is a thunk to EBC, adjust the stack pointer down 16 bytes and\r | |
122 | // put our return address and frame pointer on the VM stack.\r | |
123 | // Then set the VM's IP to new EBC code.\r | |
124 | //\r | |
125 | VmPtr->R[0] -= 8;\r | |
126 | VmWriteMemN (VmPtr, (UINTN) VmPtr->R[0], (UINTN) FramePtr);\r | |
127 | VmPtr->FramePtr = (VOID *) (UINTN) VmPtr->R[0];\r | |
128 | VmPtr->R[0] -= 8;\r | |
129 | VmWriteMem64 (VmPtr, (UINTN) VmPtr->R[0], (UINT64) (UINTN) (VmPtr->Ip + Size));\r | |
130 | \r | |
131 | VmPtr->Ip = (VMIP) (UINTN) TargetEbcAddr;\r | |
132 | } else {\r | |
133 | //\r | |
134 | // The callee is not a thunk to EBC, call native code.\r | |
135 | //\r | |
136 | EbcLLCALLEXNative (FuncAddr, NewStackPointer, FramePtr);\r | |
137 | \r | |
138 | //\r | |
139 | // Get return value and advance the IP.\r | |
140 | //\r | |
141 | VmPtr->R[7] = EbcLLGetReturnValue ();\r | |
142 | VmPtr->Ip += Size;\r | |
143 | }\r | |
144 | }\r | |
145 | \r | |
146 | STATIC\r | |
147 | UINT64\r | |
148 | EbcInterpret (\r | |
149 | IN OUT UINTN Arg1,\r | |
150 | IN OUT UINTN Arg2,\r | |
151 | IN OUT UINTN Arg3,\r | |
152 | IN OUT UINTN Arg4,\r | |
153 | IN OUT UINTN Arg5,\r | |
154 | IN OUT UINTN Arg6,\r | |
155 | IN OUT UINTN Arg7,\r | |
156 | IN OUT UINTN Arg8,\r | |
157 | IN OUT UINTN Arg9,\r | |
158 | IN OUT UINTN Arg10,\r | |
159 | IN OUT UINTN Arg11,\r | |
160 | IN OUT UINTN Arg12,\r | |
161 | IN OUT UINTN Arg13,\r | |
162 | IN OUT UINTN Arg14,\r | |
163 | IN OUT UINTN Arg15,\r | |
164 | IN OUT UINTN Arg16\r | |
165 | )\r | |
166 | /*++\r | |
167 | \r | |
168 | Routine Description:\r | |
169 | \r | |
170 | Begin executing an EBC image. The address of the entry point is passed\r | |
171 | in via a processor register, so we'll need to make a call to get the\r | |
172 | value.\r | |
173 | \r | |
174 | Arguments:\r | |
175 | \r | |
176 | None. Since we're called from a fixed up thunk (which we want to keep\r | |
177 | small), our only so-called argument is the EBC entry point passed in\r | |
178 | to us in a processor register.\r | |
179 | \r | |
180 | Returns:\r | |
181 | \r | |
182 | The value returned by the EBC application we're going to run.\r | |
183 | \r | |
184 | --*/\r | |
185 | {\r | |
186 | //\r | |
187 | // Create a new VM context on the stack\r | |
188 | //\r | |
189 | VM_CONTEXT VmContext;\r | |
190 | UINTN Addr;\r | |
191 | EFI_STATUS Status;\r | |
192 | UINTN StackIndex;\r | |
193 | \r | |
194 | //\r | |
195 | // Get the EBC entry point from the processor register.\r | |
196 | //\r | |
197 | Addr = EbcLLGetEbcEntryPoint ();\r | |
198 | \r | |
199 | //\r | |
200 | // Now clear out our context\r | |
201 | //\r | |
202 | ZeroMem ((VOID *) &VmContext, sizeof (VM_CONTEXT));\r | |
203 | \r | |
204 | //\r | |
205 | // Set the VM instruction pointer to the correct location in memory.\r | |
206 | //\r | |
207 | VmContext.Ip = (VMIP) Addr;\r | |
208 | //\r | |
209 | // Initialize the stack pointer for the EBC. Get the current system stack\r | |
210 | // pointer and adjust it down by the max needed for the interpreter.\r | |
211 | //\r | |
212 | \r | |
213 | //\r | |
214 | // Align the stack on a natural boundary\r | |
215 | //\r | |
216 | \r | |
217 | //\r | |
218 | // Allocate stack pool\r | |
219 | //\r | |
220 | Status = GetEBCStack((EFI_HANDLE)-1, &VmContext.StackPool, &StackIndex);\r | |
221 | if (EFI_ERROR(Status)) {\r | |
222 | return Status;\r | |
223 | }\r | |
224 | VmContext.StackTop = (UINT8*)VmContext.StackPool + (STACK_REMAIN_SIZE);\r | |
225 | VmContext.R[0] = (UINT64)(UINTN) ((UINT8*)VmContext.StackPool + STACK_POOL_SIZE);\r | |
226 | VmContext.HighStackBottom = (UINTN)VmContext.R[0];\r | |
227 | VmContext.R[0] &= ~(sizeof (UINTN) - 1);\r | |
228 | VmContext.R[0] -= sizeof (UINTN);\r | |
229 | \r | |
230 | //\r | |
231 | // Put a magic value in the stack gap, then adjust down again\r | |
232 | //\r | |
233 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) VM_STACK_KEY_VALUE;\r | |
234 | VmContext.StackMagicPtr = (UINTN *) (UINTN) VmContext.R[0];\r | |
235 | VmContext.LowStackTop = (UINTN) VmContext.R[0];\r | |
236 | \r | |
237 | //\r | |
238 | // For IA32, this is where we say our return address is\r | |
239 | //\r | |
240 | VmContext.R[0] -= sizeof (UINTN);\r | |
241 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg16;\r | |
242 | VmContext.R[0] -= sizeof (UINTN);\r | |
243 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg15;\r | |
244 | VmContext.R[0] -= sizeof (UINTN);\r | |
245 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg14;\r | |
246 | VmContext.R[0] -= sizeof (UINTN);\r | |
247 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg13;\r | |
248 | VmContext.R[0] -= sizeof (UINTN);\r | |
249 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg12;\r | |
250 | VmContext.R[0] -= sizeof (UINTN);\r | |
251 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg11;\r | |
252 | VmContext.R[0] -= sizeof (UINTN);\r | |
253 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg10;\r | |
254 | VmContext.R[0] -= sizeof (UINTN);\r | |
255 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg9;\r | |
256 | VmContext.R[0] -= sizeof (UINTN);\r | |
257 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg8;\r | |
258 | VmContext.R[0] -= sizeof (UINTN);\r | |
259 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg7;\r | |
260 | VmContext.R[0] -= sizeof (UINTN);\r | |
261 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg6;\r | |
262 | VmContext.R[0] -= sizeof (UINTN);\r | |
263 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg5;\r | |
264 | VmContext.R[0] -= sizeof (UINTN);\r | |
265 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg4;\r | |
266 | VmContext.R[0] -= sizeof (UINTN);\r | |
267 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg3;\r | |
268 | VmContext.R[0] -= sizeof (UINTN);\r | |
269 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg2;\r | |
270 | VmContext.R[0] -= sizeof (UINTN);\r | |
271 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) Arg1;\r | |
272 | VmContext.R[0] -= 16;\r | |
273 | VmContext.StackRetAddr = (UINT64) VmContext.R[0];\r | |
274 | \r | |
275 | //\r | |
276 | // We need to keep track of where the EBC stack starts. This way, if the EBC\r | |
277 | // accesses any stack variables above its initial stack setting, then we know\r | |
278 | // it's accessing variables passed into it, which means the data is on the\r | |
279 | // VM's stack.\r | |
280 | // When we're called, on the stack (high to low) we have the parameters, the\r | |
281 | // return address, then the saved ebp. Save the pointer to the return address.\r | |
282 | // EBC code knows that's there, so should look above it for function parameters.\r | |
283 | // The offset is the size of locals (VMContext + Addr + saved ebp).\r | |
284 | // Note that the interpreter assumes there is a 16 bytes of return address on\r | |
285 | // the stack too, so adjust accordingly.\r | |
286 | // VmContext.HighStackBottom = (UINTN)(Addr + sizeof (VmContext) + sizeof (Addr));\r | |
287 | //\r | |
288 | \r | |
289 | //\r | |
290 | // Begin executing the EBC code\r | |
291 | //\r | |
292 | EbcExecute (&VmContext);\r | |
293 | \r | |
294 | //\r | |
295 | // Return the value in R[7] unless there was an error\r | |
296 | //\r | |
297 | ReturnEBCStack(StackIndex);\r | |
298 | return (UINT64) VmContext.R[7];\r | |
299 | }\r | |
300 | \r | |
301 | STATIC\r | |
302 | UINT64\r | |
303 | ExecuteEbcImageEntryPoint (\r | |
304 | IN EFI_HANDLE ImageHandle,\r | |
305 | IN EFI_SYSTEM_TABLE *SystemTable\r | |
306 | )\r | |
307 | /*++\r | |
308 | \r | |
309 | Routine Description:\r | |
310 | \r | |
311 | Begin executing an EBC image. The address of the entry point is passed\r | |
312 | in via a processor register, so we'll need to make a call to get the\r | |
313 | value.\r | |
314 | \r | |
315 | Arguments:\r | |
316 | \r | |
317 | ImageHandle - image handle for the EBC application we're executing\r | |
318 | SystemTable - standard system table passed into an driver's entry point\r | |
319 | \r | |
320 | Returns:\r | |
321 | \r | |
322 | The value returned by the EBC application we're going to run.\r | |
323 | \r | |
324 | --*/\r | |
325 | {\r | |
326 | //\r | |
327 | // Create a new VM context on the stack\r | |
328 | //\r | |
329 | VM_CONTEXT VmContext;\r | |
330 | UINTN Addr;\r | |
331 | EFI_STATUS Status;\r | |
332 | UINTN StackIndex;\r | |
333 | \r | |
334 | //\r | |
335 | // Get the EBC entry point from the processor register. Make sure you don't\r | |
336 | // call any functions before this or you could mess up the register the\r | |
337 | // entry point is passed in.\r | |
338 | //\r | |
339 | Addr = EbcLLGetEbcEntryPoint ();\r | |
340 | \r | |
341 | //\r | |
342 | // Print(L"*** Thunked into EBC entry point - ImageHandle = 0x%X\n", (UINTN)ImageHandle);\r | |
343 | // Print(L"EBC entry point is 0x%X\n", (UINT32)(UINTN)Addr);\r | |
344 | //\r | |
345 | // Now clear out our context\r | |
346 | //\r | |
347 | ZeroMem ((VOID *) &VmContext, sizeof (VM_CONTEXT));\r | |
348 | \r | |
349 | //\r | |
350 | // Save the image handle so we can track the thunks created for this image\r | |
351 | //\r | |
352 | VmContext.ImageHandle = ImageHandle;\r | |
353 | VmContext.SystemTable = SystemTable;\r | |
354 | \r | |
355 | //\r | |
356 | // Set the VM instruction pointer to the correct location in memory.\r | |
357 | //\r | |
358 | VmContext.Ip = (VMIP) Addr;\r | |
359 | \r | |
360 | //\r | |
361 | // Initialize the stack pointer for the EBC. Get the current system stack\r | |
362 | // pointer and adjust it down by the max needed for the interpreter.\r | |
363 | //\r | |
364 | \r | |
365 | //\r | |
366 | // Allocate stack pool\r | |
367 | //\r | |
368 | Status = GetEBCStack(ImageHandle, &VmContext.StackPool, &StackIndex);\r | |
369 | if (EFI_ERROR(Status)) {\r | |
370 | return Status;\r | |
371 | }\r | |
372 | VmContext.StackTop = (UINT8*)VmContext.StackPool + (STACK_REMAIN_SIZE);\r | |
373 | VmContext.R[0] = (UINT64)(UINTN) ((UINT8*)VmContext.StackPool + STACK_POOL_SIZE);\r | |
374 | VmContext.HighStackBottom = (UINTN)VmContext.R[0];\r | |
375 | VmContext.R[0] -= sizeof (UINTN);\r | |
376 | \r | |
377 | //\r | |
378 | // Put a magic value in the stack gap, then adjust down again\r | |
379 | //\r | |
380 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) VM_STACK_KEY_VALUE;\r | |
381 | VmContext.StackMagicPtr = (UINTN *) (UINTN) VmContext.R[0];\r | |
382 | \r | |
383 | //\r | |
384 | // Align the stack on a natural boundary\r | |
385 | // VmContext.R[0] &= ~(sizeof(UINTN) - 1);\r | |
386 | //\r | |
387 | VmContext.LowStackTop = (UINTN) VmContext.R[0];\r | |
388 | VmContext.R[0] -= sizeof (UINTN);\r | |
389 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) SystemTable;\r | |
390 | VmContext.R[0] -= sizeof (UINTN);\r | |
391 | *(UINTN *) (UINTN) (VmContext.R[0]) = (UINTN) ImageHandle;\r | |
392 | \r | |
393 | VmContext.R[0] -= 16; \r | |
394 | VmContext.StackRetAddr = (UINT64) VmContext.R[0];\r | |
395 | //\r | |
396 | // VM pushes 16-bytes for return address. Simulate that here.\r | |
397 | //\r | |
398 | \r | |
399 | //\r | |
400 | // Begin executing the EBC code\r | |
401 | //\r | |
402 | EbcExecute (&VmContext);\r | |
403 | \r | |
404 | //\r | |
405 | // Return the value in R[7] unless there was an error\r | |
406 | //\r | |
407 | return (UINT64) VmContext.R[7];\r | |
408 | }\r | |
409 | \r | |
410 | EFI_STATUS\r | |
411 | EbcCreateThunks (\r | |
412 | IN EFI_HANDLE ImageHandle,\r | |
413 | IN VOID *EbcEntryPoint,\r | |
414 | OUT VOID **Thunk,\r | |
415 | IN UINT32 Flags\r | |
416 | )\r | |
417 | /*++\r | |
418 | \r | |
419 | Routine Description:\r | |
420 | \r | |
421 | Create an IA32 thunk for the given EBC entry point.\r | |
422 | \r | |
423 | Arguments:\r | |
424 | \r | |
425 | ImageHandle - Handle of image for which this thunk is being created\r | |
426 | EbcEntryPoint - Address of the EBC code that the thunk is to call\r | |
427 | Thunk - Returned thunk we create here\r | |
428 | \r | |
429 | Returns:\r | |
430 | \r | |
431 | Standard EFI status.\r | |
432 | \r | |
433 | --*/\r | |
434 | {\r | |
435 | UINT8 *Ptr;\r | |
436 | UINT8 *ThunkBase;\r | |
437 | UINT32 I;\r | |
438 | UINT32 Addr;\r | |
439 | INT32 Size;\r | |
440 | INT32 ThunkSize;\r | |
441 | \r | |
442 | //\r | |
443 | // Check alignment of pointer to EBC code\r | |
444 | //\r | |
445 | if ((UINT32) (UINTN) EbcEntryPoint & 0x01) {\r | |
446 | return EFI_INVALID_PARAMETER;\r | |
447 | }\r | |
448 | \r | |
449 | Size = EBC_THUNK_SIZE;\r | |
450 | ThunkSize = Size;\r | |
451 | \r | |
452 | Ptr = AllocatePool (Size);\r | |
453 | \r | |
454 | if (Ptr == NULL) {\r | |
455 | return EFI_OUT_OF_RESOURCES;\r | |
456 | }\r | |
457 | //\r | |
458 | // Print(L"Allocate TH: 0x%X\n", (UINT32)Ptr);\r | |
459 | //\r | |
460 | // Save the start address so we can add a pointer to it to a list later.\r | |
461 | //\r | |
462 | ThunkBase = Ptr;\r | |
463 | \r | |
464 | //\r | |
465 | // Give them the address of our buffer we're going to fix up\r | |
466 | //\r | |
467 | *Thunk = (VOID *) Ptr;\r | |
468 | \r | |
469 | //\r | |
470 | // Add a magic code here to help the VM recognize the thunk..\r | |
471 | // mov eax, 0xca112ebc => B8 BC 2E 11 CA\r | |
472 | //\r | |
473 | *Ptr = 0xB8;\r | |
474 | Ptr++;\r | |
475 | Size--;\r | |
476 | Addr = (UINT32) 0xCA112EBC;\r | |
477 | for (I = 0; I < sizeof (Addr); I++) {\r | |
478 | *Ptr = (UINT8) (UINTN) Addr;\r | |
479 | Addr >>= 8;\r | |
480 | Ptr++;\r | |
481 | Size--;\r | |
482 | }\r | |
483 | \r | |
484 | //\r | |
485 | // Add code bytes to load up a processor register with the EBC entry point.\r | |
486 | // mov eax, 0xaa55aa55 => B8 55 AA 55 AA\r | |
487 | // The first 8 bytes of the thunk entry is the address of the EBC\r | |
488 | // entry point.\r | |
489 | //\r | |
490 | *Ptr = 0xB8;\r | |
491 | Ptr++;\r | |
492 | Size--;\r | |
493 | Addr = (UINT32) EbcEntryPoint;\r | |
494 | for (I = 0; I < sizeof (Addr); I++) {\r | |
495 | *Ptr = (UINT8) (UINTN) Addr;\r | |
496 | Addr >>= 8;\r | |
497 | Ptr++;\r | |
498 | Size--;\r | |
499 | }\r | |
500 | //\r | |
501 | // Stick in a load of ecx with the address of appropriate VM function.\r | |
502 | // mov ecx 12345678h => 0xB9 0x78 0x56 0x34 0x12\r | |
503 | //\r | |
504 | if (Flags & FLAG_THUNK_ENTRY_POINT) {\r | |
505 | Addr = (UINT32) (UINTN) ExecuteEbcImageEntryPoint;\r | |
506 | } else {\r | |
507 | Addr = (UINT32) (UINTN) EbcInterpret;\r | |
508 | }\r | |
509 | \r | |
510 | //\r | |
511 | // MOV ecx\r | |
512 | //\r | |
513 | *Ptr = 0xB9;\r | |
514 | Ptr++;\r | |
515 | Size--;\r | |
516 | for (I = 0; I < sizeof (Addr); I++) {\r | |
517 | *Ptr = (UINT8) Addr;\r | |
518 | Addr >>= 8;\r | |
519 | Ptr++;\r | |
520 | Size--;\r | |
521 | }\r | |
522 | //\r | |
523 | // Stick in jump opcode bytes for jmp ecx => 0xFF 0xE1\r | |
524 | //\r | |
525 | *Ptr = 0xFF;\r | |
526 | Ptr++;\r | |
527 | Size--;\r | |
528 | *Ptr = 0xE1;\r | |
529 | Size--;\r | |
530 | \r | |
531 | //\r | |
532 | // Double check that our defined size is ok (application error)\r | |
533 | //\r | |
534 | if (Size < 0) {\r | |
535 | ASSERT (FALSE);\r | |
536 | return EFI_BUFFER_TOO_SMALL;\r | |
537 | }\r | |
538 | //\r | |
539 | // Add the thunk to the list for this image. Do this last since the add\r | |
540 | // function flushes the cache for us.\r | |
541 | //\r | |
542 | EbcAddImageThunk (ImageHandle, (VOID *) ThunkBase, ThunkSize);\r | |
543 | \r | |
544 | return EFI_SUCCESS;\r | |
545 | }\r |