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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [sparclite/] [arch/] [v2_0/] [src/] [icontext.c] - Rev 249
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/*============================================================================= // // icontext.c // // SPARClite HAL context init function // //============================================================================= //####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): hmt // Contributors: hmt // Date: 1998-12-14 // Purpose: HAL context initialization function // Description: Initialize a HAL context for SPARClite; this is in C and out // of line because there is too much of it for a simple macro. // //####DESCRIPTIONEND#### // //===========================================================================*/ #include <pkgconf/hal.h> #include <cyg/hal/hal_arch.h> // HAL header #include <cyg/infra/cyg_type.h> #include <cyg/hal/vectors.h> // SAVE_REGS_SIZE, __WINSIZE, ... /*---------------------------------------------------------------------------*/ /* We lay out the stack in the manner that the PCS demands: * frame pointer -----> [top of stack] * Argument spill area (6 words) * Return Arg pointer * Initial saved register window (i[8], l[8]) * for use by program when it starts * [rest of] saved register object (various) * stack pointer -----> saved register window (i[8], l[8]) * to allow us to be interrupted. * * ie. frame pointer -> * struct HAL_FrameStructure * stack pointer -> struct HAL_SavedRegisters * * and when the context "resumes" sp is incremented by 40 * 4, the size of * a _struct HAL_SavedRegisters_ which points it at the extant but unused * _struct HAL_FrameStructure_ as the PCS requires. The frame pointer is * left pointing off the top of stack. * * * Thus the stack is the same if created from an already executing context: * * frame pointer -----> * [temporaries and locals] * [more arguments] * Argument spill area (6 words) * Return Arg pointer * [sp at entry]------> Previous saved register window (i[8], l[8]) * for use by program when it starts * [rest of] saved register object (various) * stack pointer -----> saved register window (i[8], l[8]) * to allow us to be interrupted. */ CYG_ADDRESS hal_thread_init_context( CYG_WORD sparg, CYG_WORD thread, CYG_WORD entry, CYG_WORD id ) { register CYG_WORD fp = sparg; register CYG_WORD sp = 0; register HAL_SavedRegisters *regs; register HAL_FrameStructure *frame; int i; if ( 0 == (id & 0xffff0000) ) id <<= 16; fp &= ~15; // round down to double alignment frame = (HAL_FrameStructure *)( fp - sizeof( HAL_FrameStructure ) ); regs = (HAL_SavedRegisters *)( ((CYG_WORD)frame) - sizeof(HAL_SavedRegisters) ); sp = (CYG_WORD)regs; for ( i = 0; i < 6; i++ ) { frame->spill_args[i] = id | 0xa0 | i; } frame->composite_return_ptr = 0; for ( i = 0; i < 8; i++ ) { frame->li.i[i] = id | ( 56 + i ); frame->li.l[i] = id | ( 48 + i ); regs ->li.i[i] = id | ( 24 + i ); regs ->li.l[i] = id | ( 16 + i ); regs ->o[i] = id | ( 8 + i ); regs ->g[i] = id | ( i ); } // first terminate the linked list on the stack in the initial // (already saved) register window: frame->li.i[6] = regs->li.i[6] = (cyg_uint32)fp; // frame pointer frame->li.i[7] = regs->li.i[7] = (cyg_uint32)0; // no ret addr here // and set up other saved regs as if called from just before // the entry point: regs->o[7] = (entry - 8); regs->o[6] = sp; // this is the argument that the entry point is called with regs->o[0] = thread; // this is the initial CWP and interrupt state; CWP is quite arbitrary // really, the WIM is set up accordingly in hal_thread_load_context(). regs->g[0] = 0x0e0 + __WIN_INIT; // PIL zero, ET, S, PS and CWP set. return (CYG_ADDRESS)sp; } // --------------------------------------------------------------------------- //#define THREAD_DEBUG_SERIAL_VERBOSE #ifdef THREAD_DEBUG_SERIAL_VERBOSE // NOT INCLUDED // This is unpleasant to try to debug, because these routines are called // WHEN THE PROGRAM IS NOT RUNNING from the CygMon's GDB stubs - so you // can't use any normal output: these little routines use the serial // line directly, so are best used when debugging via Ethernet, so you // just have a separate output stream to read. Nasty... #include <cyg/hal/hal_diag.h> #undef HAL_DIAG_WRITE_CHAR #define HAL_DIAG_WRITE_CHAR(_c_) CYG_MACRO_START \ SLEB_LED = (_c_); \ HAL_DIAG_WRITE_CHAR_DIRECT( _c_ ); \ CYG_MACRO_END static void swritec( char c ) { HAL_DIAG_WRITE_CHAR( c ); } static void swrites( char *s ) { char c; while ( 0 != (c = *s++) ) HAL_DIAG_WRITE_CHAR( c ); } static void swritex( cyg_uint32 x ) { int i; swrites( "0x" ); for ( i = 28; i >= 0; i-= 4 ) { char c = "0123456789abcdef"[ 0xf & (x >> i) ]; HAL_DIAG_WRITE_CHAR( c ); } } #define newline() swrites( "\n\r" ) static void x8( char *s, unsigned long *xp ) { int i; for ( i = 0; i < 8; i++ ) { swrites( s ); swritec( '0' + i ); swrites( " = " ); swritex( xp[i] ); if ( 3 == (i & 3) ) newline(); else swrites( " " ); } } #endif // THREAD_DEBUG_SERIAL_VERBOSE ... NOT INCLUDED // --------------------------------------------------------------------------- // Routines in icontext.c used here because they're quite large for // the SPARClite (note param order); these are used in talking to GDB. enum regnames {G0 = 0, G1, G2, G3, G4, G5, G6, G7, O0, O1, O2, O3, O4, O5, SP, O7, L0, L1, L2, L3, L4, L5, L6, L7, I0, I1, I2, I3, I4, I5, FP, I7, F0, F1, F2, F3, F4, F5, F6, F7, F8, F9, F10, F11, F12, F13, F14, F15, F16, F17, F18, F19, F20, F21, F22, F23, F24, F25, F26, F27, F28, F29, F30, F31, Y, PSR, WIM, TBR, PC, NPC, FPSR, CPSR}; typedef unsigned long target_register_t; void cyg_hal_sparc_get_gdb_regs( void *gdb_regset, HAL_SavedRegisters *eCos_regset ) { target_register_t *gdb = (target_register_t *)gdb_regset; int reg; cyg_uint32 scratch = 0; cyg_uint32 *sptrap; HAL_SavedWindow *trapli, *ctxli; if ( 0 == eCos_regset->g[0] || 0xc0 == (0xe0 & eCos_regset->g[0]) ) { // Then it's an interrupt stack saved state: // (either minimal, or a saved PSR with traps disabled) // The saved register set is pretty minimal, so we have to grub // around in the stack to find out some truth... sptrap = (cyg_uint32 *)eCos_regset; // point to the IL save area for sptrap -= 24; // the trap handler, for PC, NPC trapli = (HAL_SavedWindow *)sptrap; // Get at those regs ctxli = (HAL_SavedWindow *)(trapli->i[6]); // (the frame pointer) // and get at the interruptee's regs // Pick up interruptee's registers from all over the stack: for ( reg = 0; reg < 8 ; reg++ ) { gdb[ G0 + reg ] = eCos_regset->g[reg]; gdb[ O0 + reg ] = trapli->i[reg]; gdb[ L0 + reg ] = ctxli->l[reg]; gdb[ I0 + reg ] = ctxli->i[reg]; } // Clear out G0 which is always 0 (but abused in eCos_regset) // and the FP regs which we do not have: gdb[ G0 ] = 0; for ( reg = F0; reg <= F31; reg++ ) gdb[ reg ] = 0; // In the save context _of the trap handler_ registers are as follows: // %l0 = psr (with this CWP/window-level in it) // %l1 = pc // %l2 = npc // %l3 = vector number (1-15 for interrupts) // %l4 = Y register preserved gdb[ Y ] = trapli->l[4]; scratch = trapli->l[0]; // the PSR in the trap handler #if 8 == __WINSIZE scratch++; // back to interupted thread's window scratch &=~ 0x38; // clear ET and any __WINSIZE overflow gdb[ PSR ] = scratch; gdb[ WIM ] = 1 << ((__WINBITS & (1 + scratch))); #else // 6 or 7 windows only reg = (int)(scratch & __WINBITS); scratch &=~ (__WINBITS_MAXIMAL | 0x20); // clear ET and CWP if ( __WINSIZE <= ++reg ) reg = 0; // back to intr'd window gdb[ PSR ] = scratch | reg; if ( __WINSIZE <= ++reg ) reg = 0; // good index for WIM gdb[ WIM ] = 1 << reg; #endif // __WINSIZE // Read _a_ TBR value and ignore the current trap details: asm volatile ( "rd %%tbr, %0" : "=r"(scratch) : ); gdb[ TBR ] = (scratch &~ 0xfff); gdb[ PC ] = trapli->l[1]; gdb[ NPC ] = trapli->l[2]; gdb[ FPSR ] = 0; gdb[ CPSR ] = 0; #ifdef THREAD_DEBUG_SERIAL_VERBOSE newline(); swrites( "-----------------------------------------------------" ); newline(); swrites( "-------------- INTERRUPT STACK GET ------------------" ); newline(); swrites( "eCos regset at " ); swritex( eCos_regset ); newline(); swrites( " trapli " ); swritex( trapli ); newline(); swrites( " ctxli " ); swritex( ctxli ); newline(); x8( "global ", &(gdb[G0]) ); x8( " in ", &(gdb[I0]) ); x8( " local ", &(gdb[L0]) ); x8( " out ", &(gdb[O0]) ); swrites( "gdb PC = " ); swritex( gdb[ PC ] ); newline(); swrites( "gdb NPC = " ); swritex( gdb[ NPC ] ); newline(); swrites( "gdb PSR = " ); swritex( gdb[ PSR ] ); newline(); #endif } else { // It's a synchronous context switch that led to this object. // Pick up interruptee's registers from the saved context: for ( reg = 0; reg < 8 ; reg++ ) { #ifdef CYGDBG_HAL_COMMON_CONTEXT_SAVE_MINIMUM gdb[ G0 + reg ] = 0; gdb[ O0 + reg ] = 0; #else gdb[ G0 + reg ] = eCos_regset->g[reg]; gdb[ O0 + reg ] = eCos_regset->o[reg]; #endif gdb[ L0 + reg ] = eCos_regset->li.l[reg]; gdb[ I0 + reg ] = eCos_regset->li.i[reg]; } #ifdef CYGDBG_HAL_COMMON_CONTEXT_SAVE_MINIMUM // Set up the stack pointer by arithmetic and the return address gdb[ SP ] = ((cyg_uint32)(eCos_regset)); gdb[ O7 ] = eCos_regset->o[ 7 ]; #else // Clear out G0 which is always 0 (but abused in eCos_regset) gdb[ G0 ] = 0; #endif // and clear the FP regs which we do not have: for ( reg = F0; reg <= F31; reg++ ) gdb[ reg ] = 0; gdb[ Y ] = 0; // it's not preserved. scratch = eCos_regset->g[ 0 ]; // the PSR in the saved context gdb[ PSR ] = scratch; // return it verbatim. #if 8 == __WINSIZE gdb[ WIM ] = 1 << ((__WINBITS & (1 + scratch))); #else // 6 or 7 windows only reg = (int)(scratch & __WINBITS); if ( __WINSIZE <= ++reg ) reg = 0; // good index for WIM gdb[ WIM ] = 1 << reg; #endif // __WINSIZE // Read _a_ TBR value and ignore the current trap details: asm volatile ( "rd %%tbr, %0" : "=r"(scratch) : ); gdb[ TBR ] = (scratch &~ 0xfff); gdb[ PC ] = eCos_regset->o[ 7 ]; // the return address gdb[ NPC ] = 4 + gdb[ PC ]; gdb[ FPSR ] = 0; gdb[ CPSR ] = 0; #ifdef THREAD_DEBUG_SERIAL_VERBOSE newline(); swrites( "-----------------------------------------------------" ); newline(); swrites( "-------------- SYNCHRONOUS SWITCH GET----------------" ); newline(); swrites( "eCos regset at " ); swritex( eCos_regset ); newline(); x8( "global ", &(gdb[G0]) ); x8( " in ", &(gdb[I0]) ); x8( " local ", &(gdb[L0]) ); x8( " out ", &(gdb[O0]) ); swrites( "gdb PC = " ); swritex( gdb[ PC ] ); newline(); swrites( "gdb NPC = " ); swritex( gdb[ NPC ] ); newline(); swrites( "gdb PSR = " ); swritex( gdb[ PSR ] ); newline(); #endif } } // --------------------------------------------------------------------------- void cyg_hal_sparc_set_gdb_regs( HAL_SavedRegisters *eCos_regset, void *gdb_regset ) { target_register_t *gdb = (target_register_t *)gdb_regset; int reg; cyg_uint32 scratch = 0; cyg_uint32 *sptrap; HAL_SavedWindow *trapli, *ctxli; // Guess where the eCos register set really is: if ( 0 == eCos_regset->g[0] || 0xc0 == (0xe0 & eCos_regset->g[0]) ) { // Then it's an interrupt stack saved state: // (either minimal, or a saved PSR with traps disabled) // The saved register set is pretty minimal, so we have to grub // around in the stack to find out some truth... sptrap = (cyg_uint32 *)eCos_regset; // point to the IL save area for sptrap -= 24; // the trap handler, for PC, NPC trapli = (HAL_SavedWindow *)sptrap; // Get at those regs ctxli = (HAL_SavedWindow *)(trapli->i[6]); // (the frame pointer) // and get at the interruptee's regs scratch = eCos_regset->g[0]; // Put back interruptee's registers all over the stack: for ( reg = 0; reg < 8 ; reg++ ) { eCos_regset->g[reg] = gdb[ G0 + reg ] ; trapli->i[reg] = gdb[ O0 + reg ] ; ctxli->l[reg] = gdb[ L0 + reg ] ; ctxli->i[reg] = gdb[ I0 + reg ] ; } // Put back the eCos G0 which is always 0 (but abused in eCos_regset) eCos_regset->g[0] = scratch; // In the save context _of the trap handler_ registers are as follows: // %l0 = psr (with this CWP/window-level in it) // %l1 = pc // %l2 = npc // %l3 = vector number (1-15 for interrupts) // %l4 = Y register preserved trapli->l[4] = gdb[ Y ]; // I am *not* interfering with the saved PSR, nor the TBR nor WIM. // put back return PC and NPC trapli->l[1] = gdb[ PC ] ; trapli->l[2] = gdb[ NPC ]; #ifdef THREAD_DEBUG_SERIAL_VERBOSE newline(); swrites( "-----------------------------------------------------" ); newline(); swrites( "-------------- INTERRUPT STACK SET ------------------" ); newline(); swrites( "eCos regset at " ); swritex( eCos_regset ); newline(); swrites( " trapli " ); swritex( trapli ); newline(); swrites( " ctxli " ); swritex( ctxli ); newline(); x8( "global ", &(gdb[G0]) ); x8( " in ", &(gdb[I0]) ); x8( " local ", &(gdb[L0]) ); x8( " out ", &(gdb[O0]) ); swrites( "gdb PC = " ); swritex( gdb[ PC ] ); newline(); swrites( "gdb NPC = " ); swritex( gdb[ NPC ] ); newline(); swrites( "gdb PSR = " ); swritex( gdb[ PSR ] ); newline(); #endif } else { // It's a synchronous context switch that led to this object. // Pick up interruptee's registers from the saved context: scratch = eCos_regset->g[0]; for ( reg = 0; reg < 8 ; reg++ ) { eCos_regset->g[reg] = gdb[ G0 + reg ]; eCos_regset->o[reg] = gdb[ O0 + reg ]; eCos_regset->li.l[reg] = gdb[ L0 + reg ]; eCos_regset->li.i[reg] = gdb[ I0 + reg ]; } // Put back the eCos G0 which is always 0 (but abused in eCos_regset) eCos_regset->g[0] = scratch; // I am *not* interfering with the saved PSR, nor the TBR nor WIM. // The PC is in o7, altering it via GDB's PC is not on. // Setting the NPC in a voluntary context is meaningless. #ifdef THREAD_DEBUG_SERIAL_VERBOSE newline(); swrites( "-----------------------------------------------------" ); newline(); swrites( "-------------- SYNCHRONOUS SWITCH SET ---------------" ); newline(); swrites( "eCos regset at " ); swritex( eCos_regset ); newline(); x8( "global ", &(gdb[G0]) ); x8( " in ", &(gdb[I0]) ); x8( " local ", &(gdb[L0]) ); x8( " out ", &(gdb[O0]) ); swrites( "gdb PC = " ); swritex( gdb[ PC ] ); newline(); swrites( "gdb NPC = " ); swritex( gdb[ NPC ] ); newline(); swrites( "gdb PSR = " ); swritex( gdb[ PSR ] ); newline(); #endif } } /*---------------------------------------------------------------------------*/ // EOF icontext.c
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