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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [arm/] [ebsa285/] [v2_0/] [src/] [ebsa285_misc.c] - Rev 773
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//========================================================================== // // ebsa285_misc.c // // HAL misc board support code for StrongARM EBSA285-1 // //========================================================================== //####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): gthomas // Contributors: gthomas // Date: 1999-02-20 // Purpose: HAL board support // Description: Implementations of HAL board interfaces // //####DESCRIPTIONEND#### // //========================================================================*/ #include <pkgconf/hal.h> #include <pkgconf/system.h> #include CYGBLD_HAL_PLATFORM_H #include CYGHWR_MEMORY_LAYOUT_H #include <cyg/infra/cyg_type.h> // base types #include <cyg/infra/cyg_trac.h> // tracing macros #include <cyg/infra/cyg_ass.h> // assertion macros #include <cyg/hal/hal_io.h> // IO macros #include <cyg/hal/hal_if.h> // calling interface API #include <cyg/hal/hal_arch.h> // Register state info #include <cyg/hal/hal_diag.h> #include <cyg/hal/hal_intr.h> // Interrupt names #include <cyg/hal/hal_cache.h> #include <cyg/hal/hal_ebsa285.h> // Hardware definitions #include <cyg/infra/diag.h> // diag_printf #include <string.h> // memset /* * Toggle LED for debugging purposes. */ /* * EBSA-285 Soft I/O Register */ #define EBSA_285_SOFT_IO_REGISTER ((cyg_uint32 *)0x40012000) /* * EBSA-285 Soft I/O Register Bit Field definitions */ #define EBSA_285_SOFT_IO_TOGGLE 0x80 #define EBSA_285_SOFT_IO_RED_LED 0x04 #define EBSA_285_SOFT_IO_GREEN_LED 0x02 #define EBSA_285_SOFT_IO_AMBER_LED 0x01 #define EBSA_285_SOFT_IO_J9_9_10_MASK 0x40 #define EBSA_285_SOFT_IO_J9_11_12_MASK 0x20 #define EBSA_285_SOFT_IO_J9_13_14_MASK 0x10 #define EBSA_285_SOFT_IO_SWITCH_L_MASK 0x0F static void hal_bsp_mmu_init(int sdram_size); // Some initialization has already been done before we get here. // // Set up the interrupt environment. // Set up the MMU so that we can use caches. // Enable caches. // - All done! void hal_hardware_init(void) { // Disable all interrupt sources: *SA110_IRQCONT_IRQENABLECLEAR = 0xffffffff; *SA110_IRQCONT_FIQENABLECLEAR = 0xffffffff; // including FIQ // Disable the timers *SA110_TIMER1_CONTROL = 0; *SA110_TIMER2_CONTROL = 0; *SA110_TIMER3_CONTROL = 0; *SA110_TIMER4_CONTROL = 0; *SA110_TIMER1_CLEAR = 0; // Clear any pending interrupt *SA110_TIMER2_CLEAR = 0; // (Data: don't care) *SA110_TIMER3_CLEAR = 0; *SA110_TIMER4_CLEAR = 0; // Let the timer run at a default rate (for delays) hal_clock_initialize(CYGNUM_HAL_RTC_PERIOD); // Set up MMU so that we can use caches hal_bsp_mmu_init( hal_dram_size ); // Enable caches HAL_DCACHE_ENABLE(); HAL_ICACHE_ENABLE(); // Set up eCos/ROM interfaces hal_if_init(); } // ------------------------------------------------------------------------- // MMU initialization: static void hal_bsp_mmu_init(int sdram_size) { unsigned long ttb_base = ((unsigned long)0x4000); // could be external unsigned long i; *EBSA_285_SOFT_IO_REGISTER = ~EBSA_285_SOFT_IO_RED_LED; // Red LED on // For if we assign the ttb base dynamically: // if ((ttb_base & ARM_TRANSLATION_TABLE_MASK) != ttb_base) { // // we cannot do this: // while ( 1 ) { // *EBSA_285_SOFT_IO_REGISTER = 0; // All LEDs on // for ( i = 100000; i > 0 ; i++ ) ; // *EBSA_285_SOFT_IO_REGISTER = 7; // All LEDs off // for ( i = 100000; i > 0 ; i++ ) ; //#ifdef CYG_HAL_STARTUP_RAM // return; // Do not bother looping forever... //#endif // } // } /* * Set the TTB register */ asm volatile ("mcr p15,0,%0,c2,c0,0" : : "r"(ttb_base) /*:*/ ); /* * Set the Domain Access Control Register */ i = ARM_ACCESS_TYPE_MANAGER(0) | ARM_ACCESS_TYPE_NO_ACCESS(1) | ARM_ACCESS_TYPE_NO_ACCESS(2) | ARM_ACCESS_TYPE_NO_ACCESS(3) | ARM_ACCESS_TYPE_NO_ACCESS(4) | ARM_ACCESS_TYPE_NO_ACCESS(5) | ARM_ACCESS_TYPE_NO_ACCESS(6) | ARM_ACCESS_TYPE_NO_ACCESS(7) | ARM_ACCESS_TYPE_NO_ACCESS(8) | ARM_ACCESS_TYPE_NO_ACCESS(9) | ARM_ACCESS_TYPE_NO_ACCESS(10) | ARM_ACCESS_TYPE_NO_ACCESS(11) | ARM_ACCESS_TYPE_NO_ACCESS(12) | ARM_ACCESS_TYPE_NO_ACCESS(13) | ARM_ACCESS_TYPE_NO_ACCESS(14) | ARM_ACCESS_TYPE_NO_ACCESS(15); asm volatile ("mcr p15,0,%0,c3,c0,0" : : "r"(i) /*:*/ ); /* * First clear all TT entries - ie Set them to Faulting */ memset((void *)ttb_base, 0, ARM_FIRST_LEVEL_PAGE_TABLE_SIZE); /* * We only do direct mapping for the EBSA board. That is, all * virt_addr == phys_addr. */ /* * Actual Base = 0x000(00000) * Virtual Base = 0x000(00000) * Size = Max SDRAM * SDRAM */ for (i = 0x000; i < (sdram_size >> 20); i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); } #ifdef CYGPKG_IO_PCI /* * Actual Base = CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_BASE * Virtual Base = CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_BASE * Size = CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_SIZE * Memory accessible from PCI space. Overrides part of the above mapping. */ for (i = CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_BASE >> 20; i < ((CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_BASE+CYGHWR_HAL_ARM_EBSA285_PCI_MEM_MAP_SIZE) >> 20); i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); } #endif /* * Actual Base = 0x400(00000) * Virtual Base = 0x400(00000) * Size = 1M * 21285 Registers * * Actual Base = 0x400(10000) * Virtual Base = 0x400(10000) * Size = 1M * Soft I/O port and XBus IO */ ARM_MMU_SECTION(ttb_base, 0x400, 0x400, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* * Actual Base = 0x410(00000) - 0x413(FFFFF) * Virtual Base = 0x410(00000) - 0x413(FFFFF) * Size = 4M * FLASH ROM */ for (i = 0x410; i <= 0x413; i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_CACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); } /* * Actual Base = 0x420(00000) * Virtual Base = 0x420(00000) * Size = 1M * 21285 CSR Space */ ARM_MMU_SECTION(ttb_base, 0x420, 0x420, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* * Actual Base = 0x500(00000)-0x50F(FFFFF) * Virtual Base = 0x500(00000)-0x50F(FFFFF) * Size = 16M * Zeros (Cache Clean) Bank */ for (i = 0x500; i <= 0x50F; i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); } /* * Actual Base = 0x780(00000)-0x78F(FFFFF) * Virtual Base = 0x780(00000)-0x78F(FFFFF) * Size = 16M * Outbound Write Flush */ for (i = 0x780; i <= 0x78F; i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); } /* * Actual Base = 0x790(00000)-0x7C0(FFFFF) * Virtual Base = 0x790(00000)-0x7C0(FFFFF) * Size = 65M * PCI IACK/Config/IO Space */ for (i = 0x790; i <= 0x7C0; i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); } /* * Actual Base = 0x800(00000) - 0xFFF(FFFFF) * Virtual Base = 0x800(00000) - 0xFFF(FFFFF) * Size = 2G * PCI Memory Space */ for (i = 0x800; i <= 0xFFF; i++) { ARM_MMU_SECTION(ttb_base, i, i, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); } *EBSA_285_SOFT_IO_REGISTER = ~EBSA_285_SOFT_IO_AMBER_LED; // AmberLED on } /*------------------------------------------------------------------------*/ // // Memory layout // externC cyg_uint8 * hal_arm_mem_real_region_top( cyg_uint8 *regionend ) { CYG_ASSERT( hal_dram_size > 0, "Didn't detect DRAM size!" ); CYG_ASSERT( hal_dram_size <= 256<<20, "More than 256MB reported - that can't be right" ); // is it the "normal" end of the DRAM region? If so, it should be // replaced by the real size if ( regionend == ((cyg_uint8 *)CYGMEM_REGION_ram + CYGMEM_REGION_ram_SIZE) ) { regionend = (cyg_uint8 *)CYGMEM_REGION_ram + hal_dram_size; } return regionend; } // hal_arm_mem_real_region_top() // ------------------------------------------------------------------------- static cyg_uint32 _period; void hal_clock_initialize(cyg_uint32 period) { _period = period; *SA110_TIMER3_CONTROL = 0; // Disable while we are setting up *SA110_TIMER3_LOAD = period; // Reload value *SA110_TIMER3_CLEAR = 0; // Clear any pending interrupt // (Data: don't care) *SA110_TIMER3_CONTROL = 0x000000cc; // Enable, Periodic (auto-reload), // External clock (3.68MHz on irq_in_l[2] for Timer 3) *SA110_TIMER3_CLEAR = 0; // Clear any pending interrupt again // That's all. } // This routine is called during a clock interrupt. void hal_clock_reset(cyg_uint32 vector, cyg_uint32 period) { *SA110_TIMER3_CLEAR = period; // Clear any pending interrupt (Data: don't care) } // Read the current value of the clock, returning the number of hardware // "ticks" that have occurred (i.e. how far away the current value is from // the start) void hal_clock_read(cyg_uint32 *pvalue) { *pvalue = (cyg_uint32)(_period) - *SA110_TIMER3_VALUE; } // // Delay for some number of micro-seconds // void hal_delay_us(cyg_int32 usecs) { int diff, diff2; cyg_uint32 val1, val2; while (usecs-- > 0) { diff = 0; val1 = *SA110_TIMER3_VALUE; while (diff < 3) { while ((val2 = *SA110_TIMER3_VALUE) == val1) ; if (*SA110_TIMER3_LOAD) { // A kernel is running, the counter may get reset as we watch diff2 = val2 - val1; if (diff2 < 0) diff2 += *SA110_TIMER3_LOAD; diff += diff2; } else { diff += val2 - val1; } } } } // ------------------------------------------------------------------------- // This routine is called to respond to a hardware interrupt (IRQ). It // should interrogate the hardware and return the IRQ vector number. int hal_IRQ_handler(void) { int sources; int index; #if 0 // test FIQ and print alert if active - really for debugging sources = *SA110_IRQCONT_FIQSTATUS; if ( 0 != sources ) diag_printf( "FIQ source active!!! - fiqstatus %08x irqstatus %08x\n", sources, *SA110_IRQCONT_IRQSTATUS ); else #endif // Scan FIQ sources also sources = *SA110_IRQCONT_IRQSTATUS; // if we come to support FIQ properly... // if ( 0 == sources ) // sources = *SA110_IRQCONT_FIQSTATUS; // Nothing wrong with scanning them in the order provided... // and it'll make the serial device steal fewer cycles. // So, knowing this is an ARM: if ( sources & 0xff ) index = 0; else if ( sources & 0xff00 ) index = 8; else if ( sources & 0xff0000 ) index = 16; else // if ( sources & 0xff000000 ) index = 24; do { if ( (1 << index) & sources ) return index; index++; } while ( index & 7 ); return CYGNUM_HAL_INTERRUPT_NONE; // This shouldn't happen! } // // Interrupt control // void hal_interrupt_mask(int vector) { *SA110_IRQCONT_IRQENABLECLEAR = 1 << vector; } void hal_interrupt_unmask(int vector) { *SA110_IRQCONT_IRQENABLESET = 1 << vector; } void hal_interrupt_acknowledge(int vector) { // Nothing to do here. } void hal_interrupt_configure(int vector, int level, int up) { // No interrupts are configurable on this hardware } void hal_interrupt_set_level(int vector, int level) { // No interrupts are configurable on this hardware } #include CYGHWR_MEMORY_LAYOUT_H typedef void code_fun(void); void ebsa285_program_new_stack(void *func) { register CYG_ADDRESS stack_ptr asm("sp"); register CYG_ADDRESS old_stack asm("r4"); register code_fun *new_func asm("r0"); old_stack = stack_ptr; stack_ptr = CYGMEM_REGION_ram + CYGMEM_REGION_ram_SIZE - sizeof(CYG_ADDRESS); new_func = (code_fun*)func; new_func(); stack_ptr = old_stack; return; } /*------------------------------------------------------------------------*/ // EOF ebsa285_misc.c
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