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#ifndef CYGONCE_HAL_ARCH_H #define CYGONCE_HAL_ARCH_H //============================================================================= // // hal_arch.h // // Architecture specific abstractions // //============================================================================= //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later version. // // eCos is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //============================================================================= //#####DESCRIPTIONBEGIN#### // // Author(s): nickg // Contributors: nickg // Date: 1997-09-08 // Purpose: Define architecture abstractions // Usage: #include <cyg/hal/hal_arch.h> // //####DESCRIPTIONEND#### // //============================================================================= #include <pkgconf/hal.h> #include <cyg/infra/cyg_type.h> #include <cyg/hal/ppc_regs.h> // CYGARC_REG_MSR_EE //----------------------------------------------------------------------------- // Processor saved states: typedef struct { #ifdef CYGDBG_HAL_POWERPC_FRAME_WALLS cyg_uint32 wall_head; #endif // These are common to all saved states cyg_uint32 d[32]; // Data regs #ifdef CYGHWR_HAL_POWERPC_FPU double f[32]; // Floating point registers #endif cyg_uint32 cr; // Condition Reg cyg_uint32 xer; // XER cyg_uint32 lr; // Link Reg cyg_uint32 ctr; // Count Reg // These are saved for exceptions and interrupts, but may also // be saved in a context switch if thread-aware debugging is enabled. cyg_uint32 msr; // Machine State Reg cyg_uint32 pc; // Program Counter // This marks the limit of state saved during a context switch and // is used to calculate necessary stack allocation for context switches. // It would probably be better to have a union instead... cyg_uint32 context_size[0]; // These are only saved for exceptions and interrupts cyg_uint32 vector; // Vector number #ifdef CYGDBG_HAL_POWERPC_FRAME_WALLS cyg_uint32 wall_tail; #endif } HAL_SavedRegisters; //----------------------------------------------------------------------------- // Exception handling function. // This function is defined by the kernel according to this prototype. It is // invoked from the HAL to deal with any CPU exceptions that the HAL does // not want to deal with itself. It usually invokes the kernel's exception // delivery mechanism. externC void cyg_hal_deliver_exception( CYG_WORD code, CYG_ADDRWORD data ); //----------------------------------------------------------------------------- // Bit manipulation macros #define HAL_LSBIT_INDEX(index, mask) \ asm ( "neg 11,%1;" \ "and 11,11,%1;" \ "cntlzw %0,11;" \ "subfic %0,%0,31;" \ : "=r" (index) \ : "r" (mask) \ : "r11" \ ); #define HAL_MSBIT_INDEX(index, mask) \ asm ( "cntlzw %0,%1\n" \ "subfic %0,%0,31;" \ : "=r" (index) \ : "r" (mask) \ ); //----------------------------------------------------------------------------- // eABI #define CYGARC_PPC_STACK_FRAME_SIZE 56 // size of a stack frame //----------------------------------------------------------------------------- // Context Initialization // Initialize the context of a thread. // Arguments: // _sparg_ name of variable containing current sp, will be written with new sp // _thread_ thread object address, passed as argument to entry point // _entry_ entry point address. // _id_ bit pattern used in initializing registers, for debugging. #define HAL_THREAD_INIT_CONTEXT( _sparg_, _thread_, _entry_, _id_ ) \ CYG_MACRO_START \ register CYG_WORD _sp_ = (((CYG_WORD)_sparg_) &~15) \ - CYGARC_PPC_STACK_FRAME_SIZE; \ register HAL_SavedRegisters *_regs_; \ int _i_; \ _regs_ = (HAL_SavedRegisters *)((_sp_) - sizeof(HAL_SavedRegisters)); \ for( _i_ = 0; _i_ < 32; _i_++ ) (_regs_)->d[_i_] = (_id_)|_i_; \ (_regs_)->d[01] = (CYG_WORD)(_sp_); /* SP = top of stack */ \ (_regs_)->d[03] = (CYG_WORD)(_thread_); /* R3 = arg1 = thread ptr */ \ (_regs_)->cr = 0; /* CR = 0 */ \ (_regs_)->xer = 0; /* XER = 0 */ \ (_regs_)->lr = (CYG_WORD)(_entry_); /* LR = entry point */ \ (_regs_)->pc = (CYG_WORD)(_entry_); /* set PC for thread dbg */ \ (_regs_)->ctr = 0; /* CTR = 0 */ \ (_regs_)->msr = CYGARC_REG_MSR_EE; /* MSR = enable irqs */ \ _sparg_ = (CYG_ADDRESS)_regs_; \ CYG_MACRO_END //----------------------------------------------------------------------------- // Context switch macros. // The arguments are pointers to locations where the stack pointer // of the current thread is to be stored, and from where the sp of the // next thread is to be fetched. externC void hal_thread_switch_context( CYG_ADDRESS to, CYG_ADDRESS from ); externC void hal_thread_load_context( CYG_ADDRESS to ) __attribute__ ((noreturn)); #define HAL_THREAD_SWITCH_CONTEXT(_fspptr_,_tspptr_) \ hal_thread_switch_context((CYG_ADDRESS)_tspptr_,(CYG_ADDRESS)_fspptr_); #define HAL_THREAD_LOAD_CONTEXT(_tspptr_) \ hal_thread_load_context( (CYG_ADDRESS)_tspptr_ ); //----------------------------------------------------------------------------- // Execution reorder barrier. // When optimizing the compiler can reorder code. In multithreaded systems // where the order of actions is vital, this can sometimes cause problems. // This macro may be inserted into places where reordering should not happen. #define HAL_REORDER_BARRIER() asm volatile ( "" : : : "memory" ) //----------------------------------------------------------------------------- // Breakpoint support // HAL_BREAKPOINT() is a code sequence that will cause a breakpoint to happen // if executed. // HAL_BREAKINST is the value of the breakpoint instruction and // HAL_BREAKINST_SIZE is its size in bytes. #define HAL_BREAKPOINT(_label_) \ asm volatile (" .globl " #_label_ ";" \ #_label_":" \ " trap" \ ); #define HAL_BREAKINST 0x7d821008 #define HAL_BREAKINST_SIZE 4 //----------------------------------------------------------------------------- // Thread register state manipulation for GDB support. // Translate a stack pointer as saved by the thread context macros above into // a pointer to a HAL_SavedRegisters structure. #define HAL_THREAD_GET_SAVED_REGISTERS( _sp_, _regs_ ) \ (_regs_) = (HAL_SavedRegisters *)(_sp_) // Copy a set of registers from a HAL_SavedRegisters structure into a // GDB ordered array. #define HAL_GET_GDB_REGISTERS( _aregval_, _regs_ ) \ CYG_MACRO_START \ CYG_ADDRWORD *_regval_ = (CYG_ADDRWORD *)(_aregval_); \ int _i_; \ \ for( _i_ = 0; _i_ < 32; _i_++ ) \ _regval_[_i_] = (_regs_)->d[_i_]; \ \ _regval_[64] = (_regs_)->pc; \ _regval_[65] = (_regs_)->msr; \ _regval_[66] = (_regs_)->cr; \ _regval_[67] = (_regs_)->lr; \ _regval_[68] = (_regs_)->ctr; \ _regval_[69] = (_regs_)->xer; \ CYG_MACRO_END // Copy a GDB ordered array into a HAL_SavedRegisters structure. #define HAL_SET_GDB_REGISTERS( _regs_ , _aregval_ ) \ CYG_MACRO_START \ CYG_ADDRWORD *_regval_ = (CYG_ADDRWORD *)(_aregval_); \ int _i_; \ \ for( _i_ = 0; _i_ < 32; _i_++ ) \ (_regs_)->d[_i_] = _regval_[_i_]; \ \ (_regs_)->pc = _regval_[64]; \ (_regs_)->msr = _regval_[65]; \ (_regs_)->cr = _regval_[66]; \ (_regs_)->lr = _regval_[67]; \ (_regs_)->ctr = _regval_[68]; \ (_regs_)->xer = _regval_[69]; \ CYG_MACRO_END //----------------------------------------------------------------------------- // HAL setjmp typedef struct { cyg_uint32 sp; cyg_uint32 r2; cyg_uint32 r13; cyg_uint32 r14; cyg_uint32 r15; cyg_uint32 r16; cyg_uint32 r17; cyg_uint32 r18; cyg_uint32 r19; cyg_uint32 r20; cyg_uint32 r21; cyg_uint32 r22; cyg_uint32 r23; cyg_uint32 r24; cyg_uint32 r25; cyg_uint32 r26; cyg_uint32 r27; cyg_uint32 r28; cyg_uint32 r29; cyg_uint32 r30; cyg_uint32 r31; #ifdef CYGHWR_HAL_POWERPC_FPU double f14; double f15; double f16; double f17; double f18; double f19; double f20; double f21; double f22; double f23; double f24; double f25; double f26; double f27; double f28; double f29; double f30; double f31; #endif cyg_uint32 lr; cyg_uint32 cr; } hal_jmp_buf_t; #define CYGARC_JMP_BUF_SIZE (sizeof(hal_jmp_buf_t) / sizeof(cyg_uint32)) typedef cyg_uint32 hal_jmp_buf[ CYGARC_JMP_BUF_SIZE ]; externC int hal_setjmp(hal_jmp_buf env); externC void hal_longjmp(hal_jmp_buf env, int val); //----------------------------------------------------------------------------- // Idle thread code. // This macro is called in the idle thread loop, and gives the HAL the // chance to insert code. Typical idle thread behaviour might be to halt the // processor. externC void hal_idle_thread_action(cyg_uint32 loop_count); #define HAL_IDLE_THREAD_ACTION(_count_) hal_idle_thread_action(_count_) //----------------------------------------------------------------------------- // Minimal and sensible stack sizes: the intention is that applications // will use these to provide a stack size in the first instance prior to // proper analysis. Idle thread stack should be this big. // THESE ARE NOT INTENDED TO BE MICROMETRICALLY ACCURATE FIGURES. // THEY ARE HOWEVER ENOUGH TO START PROGRAMMING. // YOU MUST MAKE YOUR STACKS LARGER IF YOU HAVE LARGE "AUTO" VARIABLES! // This is not a config option because it should not be adjusted except // under "enough rope" sort of disclaimers. // Stack frame overhead per call. The PPC ABI defines regs 13..31 as callee // saved. callee saved variables are irrelevant for us as they would contain // automatic variables, so we only count the caller-saved regs here // So that makes r0..r12 + cr, xer, lr, ctr: #define CYGNUM_HAL_STACK_FRAME_SIZE (4 * 17) // Stack needed for a context switch #define CYGNUM_HAL_STACK_CONTEXT_SIZE \ (38*4 /* offsetof(HAL_SavedRegisters, context_size) */) // Interrupt + call to ISR, interrupt_end() and the DSR #define CYGNUM_HAL_STACK_INTERRUPT_SIZE \ ((43*4 /* sizeof(HAL_SavedRegisters) */) + 2 * CYGNUM_HAL_STACK_FRAME_SIZE) // We have lots of registers so no particular amount is added in for // typical local variable usage. // We define a minimum stack size as the minimum any thread could ever // legitimately get away with. We can throw asserts if users ask for less // than this. Allow enough for three interrupt sources - clock, serial and // one other #ifdef CYGIMP_HAL_COMMON_INTERRUPTS_USE_INTERRUPT_STACK // An interrupt stack which is large enough for all possible interrupt // conditions (and only used for that purpose) exists. "User" stacks // can therefore be much smaller # define CYGNUM_HAL_STACK_SIZE_MINIMUM \ (16*CYGNUM_HAL_STACK_FRAME_SIZE + 2*CYGNUM_HAL_STACK_INTERRUPT_SIZE) #else // No separate interrupt stack exists. Make sure all threads contain // a stack sufficiently large # define CYGNUM_HAL_STACK_SIZE_MINIMUM \ (((2+3)*CYGNUM_HAL_STACK_INTERRUPT_SIZE) + \ (16*CYGNUM_HAL_STACK_FRAME_SIZE)) #endif // Now make a reasonable choice for a typical thread size. Pluck figures // from thin air and say 30 call frames with an average of 16 words of // automatic variables per call frame #define CYGNUM_HAL_STACK_SIZE_TYPICAL \ (CYGNUM_HAL_STACK_SIZE_MINIMUM + \ 30 * (CYGNUM_HAL_STACK_FRAME_SIZE+(16*4))) //-------------------------------------------------------------------------- // Macros for switching context between two eCos instances (jump from // code in ROM to code in RAM or vice versa). // Should be defined like for MIPS, saving/restoring R2 - but is it // actually used? I've never seen app code use R2. Something to investigate. #define CYGARC_HAL_SAVE_GP() #define CYGARC_HAL_RESTORE_GP() //----------------------------------------------------------------------------- #endif // CYGONCE_HAL_ARCH_H // End of hal_arch.h