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[/] [or1k/] [trunk/] [rtems/] [c/] [src/] [exec/] [score/] [cpu/] [sparc/] [cpu.c] - Rev 158
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/* * SPARC Dependent Source * * COPYRIGHT (c) 1989-1999. * On-Line Applications Research Corporation (OAR). * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * Ported to ERC32 implementation of the SPARC by On-Line Applications * Research Corporation (OAR) under contract to the European Space * Agency (ESA). * * ERC32 modifications of respective RTEMS file: COPYRIGHT (c) 1995. * European Space Agency. * * $Id: cpu.c,v 1.1.1.1 2001-07-10 09:45:43 chris Exp $ */ #include <rtems/system.h> #include <rtems/score/isr.h> #if defined(erc32) #include <erc32.h> #endif /* * This initializes the set of opcodes placed in each trap * table entry. The routine which installs a handler is responsible * for filling in the fields for the _handler address and the _vector * trap type. * * The constants following this structure are masks for the fields which * must be filled in when the handler is installed. */ const CPU_Trap_table_entry _CPU_Trap_slot_template = { 0xa1480000, /* mov %psr, %l0 */ 0x29000000, /* sethi %hi(_handler), %l4 */ 0x81c52000, /* jmp %l4 + %lo(_handler) */ 0xa6102000 /* mov _vector, %l3 */ }; /*PAGE * * _CPU_Initialize * * This routine performs processor dependent initialization. * * Input Parameters: * cpu_table - CPU table to initialize * thread_dispatch - address of disptaching routine * * Output Parameters: NONE * * NOTE: There is no need to save the pointer to the thread dispatch routine. * The SPARC's assembly code can reference it directly with no problems. */ void _CPU_Initialize( rtems_cpu_table *cpu_table, void (*thread_dispatch) /* ignored on this CPU */ ) { void *pointer; #ifndef NO_TABLE_MOVE unsigned32 trap_table_start; unsigned32 tbr_value; CPU_Trap_table_entry *old_tbr; CPU_Trap_table_entry *trap_table; /* * Install the executive's trap table. All entries from the original * trap table are copied into the executive's trap table. This is essential * since this preserves critical trap handlers such as the window underflow * and overflow handlers. It is the responsibility of the BSP to provide * install these in the initial trap table. */ trap_table_start = (unsigned32) &_CPU_Trap_Table_area; if (trap_table_start & (SPARC_TRAP_TABLE_ALIGNMENT-1)) trap_table_start = (trap_table_start + SPARC_TRAP_TABLE_ALIGNMENT) & ~(SPARC_TRAP_TABLE_ALIGNMENT-1); trap_table = (CPU_Trap_table_entry *) trap_table_start; sparc_get_tbr( tbr_value ); old_tbr = (CPU_Trap_table_entry *) (tbr_value & 0xfffff000); memcpy( trap_table, (void *) old_tbr, 256 * sizeof( CPU_Trap_table_entry ) ); sparc_set_tbr( trap_table_start ); #endif /* * This seems to be the most appropriate way to obtain an initial * FP context on the SPARC. The NULL fp context is copied it to * the task's FP context during Context_Initialize. */ pointer = &_CPU_Null_fp_context; _CPU_Context_save_fp( &pointer ); /* * Grab our own copy of the user's CPU table. */ _CPU_Table = *cpu_table; #if defined(erc32) /* * ERC32 specific initialization */ _ERC32_MEC_Timer_Control_Mirror = 0; ERC32_MEC.Timer_Control = 0; ERC32_MEC.Control |= ERC32_CONFIGURATION_POWER_DOWN_ALLOWED; #endif } /*PAGE * * _CPU_ISR_Get_level * * Input Parameters: NONE * * Output Parameters: * returns the current interrupt level (PIL field of the PSR) */ unsigned32 _CPU_ISR_Get_level( void ) { unsigned32 level; sparc_get_interrupt_level( level ); return level; } /*PAGE * * _CPU_ISR_install_raw_handler * * This routine installs the specified handler as a "raw" non-executive * supported trap handler (a.k.a. interrupt service routine). * * Input Parameters: * vector - trap table entry number plus synchronous * vs. asynchronous information * new_handler - address of the handler to be installed * old_handler - pointer to an address of the handler previously installed * * Output Parameters: NONE * *new_handler - address of the handler previously installed * * NOTE: * * On the SPARC, there are really only 256 vectors. However, the executive * has no easy, fast, reliable way to determine which traps are synchronous * and which are asynchronous. By default, synchronous traps return to the * instruction which caused the interrupt. So if you install a software * trap handler as an executive interrupt handler (which is desirable since * RTEMS takes care of window and register issues), then the executive needs * to know that the return address is to the trap rather than the instruction * following the trap. * * So vectors 0 through 255 are treated as regular asynchronous traps which * provide the "correct" return address. Vectors 256 through 512 are assumed * by the executive to be synchronous and to require that the return address * be fudged. * * If you use this mechanism to install a trap handler which must reexecute * the instruction which caused the trap, then it should be installed as * an asynchronous trap. This will avoid the executive changing the return * address. */ void _CPU_ISR_install_raw_handler( unsigned32 vector, proc_ptr new_handler, proc_ptr *old_handler ) { unsigned32 real_vector; CPU_Trap_table_entry *tbr; CPU_Trap_table_entry *slot; unsigned32 u32_tbr; unsigned32 u32_handler; /* * Get the "real" trap number for this vector ignoring the synchronous * versus asynchronous indicator included with our vector numbers. */ real_vector = SPARC_REAL_TRAP_NUMBER( vector ); /* * Get the current base address of the trap table and calculate a pointer * to the slot we are interested in. */ sparc_get_tbr( u32_tbr ); u32_tbr &= 0xfffff000; tbr = (CPU_Trap_table_entry *) u32_tbr; slot = &tbr[ real_vector ]; /* * Get the address of the old_handler from the trap table. * * NOTE: The old_handler returned will be bogus if it does not follow * the RTEMS model. */ #define HIGH_BITS_MASK 0xFFFFFC00 #define HIGH_BITS_SHIFT 10 #define LOW_BITS_MASK 0x000003FF if ( slot->mov_psr_l0 == _CPU_Trap_slot_template.mov_psr_l0 ) { u32_handler = ((slot->sethi_of_handler_to_l4 & HIGH_BITS_MASK) << HIGH_BITS_SHIFT) | (slot->jmp_to_low_of_handler_plus_l4 & LOW_BITS_MASK); *old_handler = (proc_ptr) u32_handler; } else *old_handler = 0; /* * Copy the template to the slot and then fix it. */ *slot = _CPU_Trap_slot_template; u32_handler = (unsigned32) new_handler; slot->mov_vector_l3 |= vector; slot->sethi_of_handler_to_l4 |= (u32_handler & HIGH_BITS_MASK) >> HIGH_BITS_SHIFT; slot->jmp_to_low_of_handler_plus_l4 |= (u32_handler & LOW_BITS_MASK); } /*PAGE * * _CPU_ISR_install_vector * * This kernel routine installs the RTEMS handler for the * specified vector. * * Input parameters: * vector - interrupt vector number * new_handler - replacement ISR for this vector number * old_handler - pointer to former ISR for this vector number * * Output parameters: * *old_handler - former ISR for this vector number * */ void _CPU_ISR_install_vector( unsigned32 vector, proc_ptr new_handler, proc_ptr *old_handler ) { unsigned32 real_vector; proc_ptr ignored; /* * Get the "real" trap number for this vector ignoring the synchronous * versus asynchronous indicator included with our vector numbers. */ real_vector = SPARC_REAL_TRAP_NUMBER( vector ); /* * Return the previous ISR handler. */ *old_handler = _ISR_Vector_table[ real_vector ]; /* * Install the wrapper so this ISR can be invoked properly. */ _CPU_ISR_install_raw_handler( vector, _ISR_Handler, &ignored ); /* * We put the actual user ISR address in '_ISR_vector_table'. This will * be used by the _ISR_Handler so the user gets control. */ _ISR_Vector_table[ real_vector ] = new_handler; } /*PAGE * * _CPU_Context_Initialize * * This kernel routine initializes the basic non-FP context area associated * with each thread. * * Input parameters: * the_context - pointer to the context area * stack_base - address of memory for the SPARC * size - size in bytes of the stack area * new_level - interrupt level for this context area * entry_point - the starting execution point for this this context * is_fp - TRUE if this context is associated with an FP thread * * Output parameters: NONE */ void _CPU_Context_Initialize( Context_Control *the_context, unsigned32 *stack_base, unsigned32 size, unsigned32 new_level, void *entry_point, boolean is_fp ) { unsigned32 stack_high; /* highest "stack aligned" address */ unsigned32 the_size; unsigned32 tmp_psr; /* * On CPUs with stacks which grow down (i.e. SPARC), we build the stack * based on the stack_high address. */ stack_high = ((unsigned32)(stack_base) + size); stack_high &= ~(CPU_STACK_ALIGNMENT - 1); the_size = size & ~(CPU_STACK_ALIGNMENT - 1); /* * See the README in this directory for a diagram of the stack. */ the_context->o7 = ((unsigned32) entry_point) - 8; the_context->o6_sp = stack_high - CPU_MINIMUM_STACK_FRAME_SIZE; the_context->i6_fp = stack_high; /* * Build the PSR for the task. Most everything can be 0 and the * CWP is corrected during the context switch. * * The EF bit determines if the floating point unit is available. * The FPU is ONLY enabled if the context is associated with an FP task * and this SPARC model has an FPU. */ sparc_get_psr( tmp_psr ); tmp_psr &= ~SPARC_PSR_PIL_MASK; tmp_psr |= (new_level << 8) & SPARC_PSR_PIL_MASK; tmp_psr &= ~SPARC_PSR_EF_MASK; /* disabled by default */ #if (SPARC_HAS_FPU == 1) /* * If this bit is not set, then a task gets a fault when it accesses * a floating point register. This is a nice way to detect floating * point tasks which are not currently declared as such. */ if ( is_fp ) tmp_psr |= SPARC_PSR_EF_MASK; #endif the_context->psr = tmp_psr; } /*PAGE * * _CPU_Thread_Idle_body * * Some SPARC implementations have low power, sleep, or idle modes. This * tries to take advantage of those models. */ #if (CPU_PROVIDES_IDLE_THREAD_BODY == TRUE) /* * This is the implementation for the erc32. * * NOTE: Low power mode was enabled at initialization time. */ #if defined(erc32) void _CPU_Thread_Idle_body( void ) { while (1) { ERC32_MEC.Power_Down = 0; /* value is irrelevant */ } } #endif #endif /* CPU_PROVIDES_IDLE_THREAD_BODY */
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