/** @file PEI Dispatcher Dependency Evaluator This routine evaluates a dependency expression (DEPENDENCY_EXPRESSION) to determine if a driver can be scheduled for execution. The criteria for schedulability is that the dependency expression is satisfied. Copyright (c) 2006, Intel Corporation All rights reserved. This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License which accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. **/ #include #include "dependency.h" /** This routine determines if a PPI has been installed. The truth value of a GUID is determined by if the PPI has been published and can be queried from the PPI database. @param PeiServices The PEI core services table. @param Stack Reference to EVAL_STACK_ENTRY that contains PPI GUID to check @retval TRUE if the PPI is already installed. @retval FALSE if the PPI has yet to be installed. **/ BOOLEAN IsPpiInstalled ( IN EFI_PEI_SERVICES **PeiServices, IN EVAL_STACK_ENTRY *Stack ) { VOID *PeiInstance; EFI_STATUS Status; EFI_GUID PpiGuid; // // If there is no GUID to evaluate, just return current result on stack. // if (Stack->Operator == NULL) { return Stack->Result; } // // Copy the Guid into a locale variable so that there are no // possibilities of alignment faults for cross-compilation // environments such as Intel?Itanium(TM). // CopyMem(&PpiGuid, Stack->Operator, sizeof(EFI_GUID)); // // Check if the PPI is installed. // Status = PeiServicesLocatePpi( &PpiGuid, // GUID 0, // INSTANCE NULL, // EFI_PEI_PPI_DESCRIPTOR &PeiInstance // PPI ); if (EFI_ERROR(Status)) { return FALSE; } return TRUE; } /** This is the POSTFIX version of the dependency evaluator. When a PUSH [PPI GUID] is encountered, a pointer to the GUID is stored on the evaluation stack. When that entry is poped from the evaluation stack, the PPI is checked if it is installed. This method allows some time savings as not all PPIs must be checked for certain operation types (AND, OR). @param PeiServices Calling context. @param DependencyExpression Pointer to a dependency expression. The Grammar adheres to the BNF described above and is stored in postfix notation. @retval TRUE if it is a well-formed Grammar @retval FALSE if the dependency expression overflows the evaluation stack if the dependency expression underflows the evaluation stack if the dependency expression is not a well-formed Grammar. **/ BOOLEAN PeimDispatchReadiness ( IN EFI_PEI_SERVICES **PeiServices, IN VOID *DependencyExpression ) { DEPENDENCY_EXPRESSION_OPERAND *Iterator; EVAL_STACK_ENTRY *StackPtr; EVAL_STACK_ENTRY EvalStack[MAX_GRAMMAR_SIZE]; Iterator = DependencyExpression; StackPtr = &EvalStack[0]; while (TRUE) { switch (*(Iterator++)) { // // For performance reason we put the frequently used items in front of // the rarely used items // case (EFI_DEP_PUSH): // // Check to make sure the dependency grammar doesn't overflow the // EvalStack on the push // if (StackPtr > &EvalStack[MAX_GRAMMAR_SIZE-1]) { return FALSE; } // // Push the pointer to the PUSH opcode operator (pointer to PPI GUID) // We will evaluate if the PPI is insalled on the POP operation. // StackPtr->Operator = (VOID *) Iterator; Iterator = Iterator + sizeof (EFI_GUID); StackPtr++; break; case (EFI_DEP_AND): case (EFI_DEP_OR): // // Check to make sure the dependency grammar doesn't underflow the // EvalStack on the two POPs for the AND operation. Don't need to // check for the overflow on PUSHing the result since we already // did two POPs. // if (StackPtr < &EvalStack[2]) { return FALSE; } // // Evaluate the first POPed operator only. If the operand is // EFI_DEP_AND and the POPed operator evaluates to FALSE, or the // operand is EFI_DEP_OR and the POPed operator evaluates to TRUE, // we don't need to check the second operator, and the result will be // evaluation of the POPed operator. Otherwise, don't POP the second // operator since it will now evaluate to the final result on the // next operand that causes a POP. // StackPtr--; // // Iterator has increased by 1 after we retrieve the operand, so here we // should get the value pointed by (Iterator - 1), in order to obtain the // same operand. // if (*(Iterator - 1) == EFI_DEP_AND) { if (!(IsPpiInstalled (PeiServices, StackPtr))) { (StackPtr-1)->Result = FALSE; (StackPtr-1)->Operator = NULL; } } else { if (IsPpiInstalled (PeiServices, StackPtr)) { (StackPtr-1)->Result = TRUE; (StackPtr-1)->Operator = NULL; } } break; case (EFI_DEP_END): StackPtr--; // // Check to make sure EvalStack is balanced. If not, then there is // an error in the dependency grammar, so return EFI_INVALID_PARAMETER. // if (StackPtr != &EvalStack[0]) { return FALSE; } return IsPpiInstalled (PeiServices, StackPtr); break; case (EFI_DEP_NOT): // // Check to make sure the dependency grammar doesn't underflow the // EvalStack on the POP for the NOT operation. Don't need to // check for the overflow on PUSHing the result since we already // did a POP. // if (StackPtr < &EvalStack[1]) { return FALSE; } (StackPtr-1)->Result = (BOOLEAN) !IsPpiInstalled (PeiServices, (StackPtr-1)); (StackPtr-1)->Operator = NULL; break; case (EFI_DEP_TRUE): case (EFI_DEP_FALSE): // // Check to make sure the dependency grammar doesn't overflow the // EvalStack on the push // if (StackPtr > &EvalStack[MAX_GRAMMAR_SIZE-1]) { return FALSE; } // // Iterator has increased by 1 after we retrieve the operand, so here we // should get the value pointed by (Iterator - 1), in order to obtain the // same operand. // if (*(Iterator - 1) == EFI_DEP_TRUE) { StackPtr->Result = TRUE; } else { StackPtr->Result = FALSE; } StackPtr->Operator = NULL; StackPtr++; break; default: // // The grammar should never arrive here // return FALSE; break; } } }