URL
https://opencores.org/ocsvn/openrisc_me/openrisc_me/trunk
Subversion Repositories openrisc_me
[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [arm/] [arm9/] [innovator/] [v2_0/] [src/] [innovator_misc.c] - Rev 307
Go to most recent revision | Compare with Previous | Blame | View Log
//========================================================================== // // innovator_misc.c // // HAL misc board support code for ARM9/INNOVATOR // //========================================================================== //####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): Patrick Doyle <wpd@delcomsys.com> // Contributors: Patrick Doyle <wpd@delcomsys.com> // Date: 2002-12-17 // 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 <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_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/innovator.h> // Platform specifics #include <cyg/infra/diag.h> // diag_printf #include <string.h> // memset // ------------------------------------------------------------------------- // MMU initialization: // // These structures are laid down in memory to define the translation // table. // // ARM Translation Table Base Bit Masks #define ARM_TRANSLATION_TABLE_MASK 0xFFFFC000 // ARM Domain Access Control Bit Masks #define ARM_ACCESS_TYPE_NO_ACCESS(domain_num) (0x0 << (domain_num)*2) #define ARM_ACCESS_TYPE_CLIENT(domain_num) (0x1 << (domain_num)*2) #define ARM_ACCESS_TYPE_MANAGER(domain_num) (0x3 << (domain_num)*2) struct ARM_MMU_FIRST_LEVEL_FAULT { int id : 2; int sbz : 30; }; #define ARM_MMU_FIRST_LEVEL_FAULT_ID 0x0 struct ARM_MMU_FIRST_LEVEL_PAGE_TABLE { int id : 2; int imp : 2; int domain : 4; int sbz : 1; int base_address : 23; }; #define ARM_MMU_FIRST_LEVEL_PAGE_TABLE_ID 0x1 struct ARM_MMU_FIRST_LEVEL_SECTION { int id : 2; int b : 1; int c : 1; int imp : 1; int domain : 4; int sbz0 : 1; int ap : 2; int sbz1 : 8; int base_address : 12; }; #define ARM_MMU_FIRST_LEVEL_SECTION_ID 0x2 struct ARM_MMU_FIRST_LEVEL_RESERVED { int id : 2; int sbz : 30; }; #define ARM_MMU_FIRST_LEVEL_RESERVED_ID 0x3 #define ARM_MMU_FIRST_LEVEL_DESCRIPTOR_ADDRESS(ttb_base, table_index) \ (unsigned long *)((unsigned long)(ttb_base) + ((table_index) << 2)) #define ARM_FIRST_LEVEL_PAGE_TABLE_SIZE 0x4000 #define ARM_MMU_SECTION(ttb_base, actual_base, virtual_base, \ cacheable, bufferable, perm) \ CYG_MACRO_START \ register union ARM_MMU_FIRST_LEVEL_DESCRIPTOR desc; \ \ desc.word = 0; \ desc.section.id = ARM_MMU_FIRST_LEVEL_SECTION_ID; \ desc.section.imp = 1; \ desc.section.domain = 0; \ desc.section.c = (cacheable); \ desc.section.b = (bufferable); \ desc.section.ap = (perm); \ desc.section.base_address = (actual_base); \ *ARM_MMU_FIRST_LEVEL_DESCRIPTOR_ADDRESS(ttb_base, (virtual_base)) \ = desc.word; \ CYG_MACRO_END #define X_ARM_MMU_SECTION(abase,vbase,size,cache,buff,access) \ { int i; int j = abase; int k = vbase; \ for (i = size; i > 0 ; i--,j++,k++) \ { \ ARM_MMU_SECTION(ttb_base, j, k, cache, buff, access); \ } \ } union ARM_MMU_FIRST_LEVEL_DESCRIPTOR { unsigned long word; struct ARM_MMU_FIRST_LEVEL_FAULT fault; struct ARM_MMU_FIRST_LEVEL_PAGE_TABLE page_table; struct ARM_MMU_FIRST_LEVEL_SECTION section; struct ARM_MMU_FIRST_LEVEL_RESERVED reserved; }; #define ARM_UNCACHEABLE 0 #define ARM_CACHEABLE 1 #define ARM_UNBUFFERABLE 0 #define ARM_BUFFERABLE 1 #define ARM_ACCESS_PERM_NONE_NONE 0 #define ARM_ACCESS_PERM_RO_NONE 0 #define ARM_ACCESS_PERM_RO_RO 0 #define ARM_ACCESS_PERM_RW_NONE 1 #define ARM_ACCESS_PERM_RW_RO 2 #define ARM_ACCESS_PERM_RW_RW 3 void hal_mmu_init(void) { unsigned long ttb_base = INNOVATOR_SDRAM_PHYS_BASE + 0x4000; unsigned long i; // 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); // Actual Virtual Size Attributes Function // Base Base MB cached? buffered? access permissions // xxx00000 xxx00000 X_ARM_MMU_SECTION(0x000, 0x100, 4, ARM_CACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); // FLASH CS0 X_ARM_MMU_SECTION(0x100, 0x000, 32, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); // SDRAM X_ARM_MMU_SECTION(0x080, 0x080, 1, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); // FPGA X_ARM_MMU_SECTION(0x200, 0x200, 1, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); // Internal SRAM X_ARM_MMU_SECTION(0xE00, 0xE00, 512, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); // Internal Peripherals } //---------------------------------------------------------------------------- // Platform specific initialization void plf_hardware_init(void) { #ifdef LATER // Disable PLD interrupts HAL_WRITE_UINT32(INNOVATOR_INT_MASK_CLEAR, INNOVATOR_INT_SOURCE_P0 | INNOVATOR_INT_SOURCE_P1 | INNOVATOR_INT_SOURCE_P2 | INNOVATOR_INT_SOURCE_P3 | INNOVATOR_INT_SOURCE_P4 | INNOVATOR_INT_SOURCE_P5); // Make PLD0 generate IRQ HAL_WRITE_UINT32(INNOVATOR_INT_PRIORITY_0, 0); #endif cyg_uint8 tmp; // This should be protected by some sort of #ifdef to test to see if // the ethernet has been enabled or not. I'll add that later. HAL_READ_UINT8(0x0800000B, tmp); HAL_WRITE_UINT8(0x0800000B, tmp & ~1); HAL_DELAY_US(750); } // ------------------------------------------------------------------------- void hal_clock_initialize(cyg_uint32 period) { #ifdef LATER cyg_uint32 cr; HAL_WRITE_UINT32(INNOVATOR_TIMER0_CR, 0); HAL_WRITE_UINT32(INNOVATOR_TIMER0_PRE, CYGNUM_HAL_ARM_INNOVATOR_TIMER_PRESCALE - 1); HAL_WRITE_UINT32(INNOVATOR_TIMER0_LIMIT, period); cr = INNOVATOR_TIMER_CR_MODE_HEARBEAT | INNOVATOR_TIMER_CR_IE; HAL_WRITE_UINT32(INNOVATOR_TIMER0_CR, cr); HAL_WRITE_UINT32(INNOVATOR_TIMER0_CR, cr | INNOVATOR_TIMER_CR_S); // Unmask timer 0 interrupt HAL_INTERRUPT_CONFIGURE( CYGNUM_HAL_INTERRUPT_RTC, 1, 1 ); HAL_INTERRUPT_UNMASK( CYGNUM_HAL_INTERRUPT_RTC ); #endif } // This routine is called during a clock interrupt. void hal_clock_reset(cyg_uint32 vector, cyg_uint32 period) { #ifdef LATER cyg_uint32 cr; // Clear pending interrupt bit HAL_READ_UINT32(INNOVATOR_TIMER0_CR, cr); cr |= INNOVATOR_TIMER_CR_CI; HAL_WRITE_UINT32(INNOVATOR_TIMER0_CR, cr); #endif } // 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) { #ifdef LATER cyg_uint32 ctr; HAL_READ_UINT32(INNOVATOR_TIMER0_READ, ctr); *pvalue = ctr; #endif } // // Delay for some number of micro-seconds // void hal_delay_us(cyg_int32 usecs) { #ifdef LATER // Use timer 2 cyg_uint32 cr; // Divide by 1000000 in two steps to preserve precision. cyg_uint32 wait_clocks = ((CYGNUM_HAL_ARM_INNOVATOR_PERIPHERAL_CLOCK/100000)*usecs)/10; HAL_WRITE_UINT32(INNOVATOR_TIMER1_CR, 0); HAL_WRITE_UINT32(INNOVATOR_TIMER1_PRE, 0); HAL_WRITE_UINT32(INNOVATOR_TIMER1_LIMIT, wait_clocks); cr = INNOVATOR_TIMER_CR_MODE_ONE_SHOT|INNOVATOR_TIMER_CR_CI; HAL_WRITE_UINT32(INNOVATOR_TIMER1_CR, cr); HAL_WRITE_UINT32(INNOVATOR_TIMER1_CR, cr | INNOVATOR_TIMER_CR_S); // wait for start bit to clear do { HAL_READ_UINT32(INNOVATOR_TIMER1_CR, cr); } while ((INNOVATOR_TIMER_CR_S & cr) != 0); //clear interrupt flag HAL_WRITE_UINT32(INNOVATOR_TIMER1_CR, 0); #else #if 0 volatile unsigned long long x; volatile unsigned long long loop_count = usecs / 10 + 1; for (x = 0; x < loop_count; x++) ; #else volatile cyg_uint32 *CNTL_TIMER = (volatile cyg_uint32 *)(0xFFFEC500 + 0x00); volatile cyg_uint32 *LOAD_TIM = (volatile cyg_uint32 *)(0xFFFEC500 + 0x04); volatile cyg_uint32 *READ_TIM = (volatile cyg_uint32 *)(0xFFFEC500 + 0x08); cyg_uint32 timer_val, prev_val; int too_long = 0; if (usecs <= 0) { return; } else if (usecs > 357913941) { /* Clamp at MAX_INT32 / 6 */ usecs = 357913941; } /* Enable the clock and halt the timer */ HAL_WRITE_UINT32(CNTL_TIMER, 0x00000020); /* Load the timer */ HAL_WRITE_UINT32(LOAD_TIM, 6 * usecs); /* Start the timer */ HAL_READ_UINT32(READ_TIM, prev_val); HAL_WRITE_UINT32(CNTL_TIMER, 0x00000021); /* Wait for it to load (but not too long) */ do { HAL_READ_UINT32(READ_TIM, timer_val); if (++too_long >= 100) { break; } } while (timer_val == prev_val); /* Wait for it to count down to zero */ do { HAL_READ_UINT32(READ_TIM, timer_val); } while (timer_val > 0); #endif #endif } // ------------------------------------------------------------------------- // 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) { #ifdef LATER int vec; cyg_uint32 isr; HAL_READ_UINT32(INNOVATOR_INT_REQUEST_STATUS, isr); for (vec = CYGNUM_HAL_INTERRUPT_PLD_0; vec <= CYGNUM_HAL_INTERRUPT_FAST_COMMS; vec++) { if (isr & (1<<vec)) { return vec; } } #endif return CYGNUM_HAL_INTERRUPT_NONE; } //---------------------------------------------------------------------------- // Interrupt control // void hal_interrupt_mask(int vector) { #ifdef LATER CYG_ASSERT(vector <= CYGNUM_HAL_ISR_MAX && vector >= CYGNUM_HAL_ISR_MIN , "Invalid vector"); HAL_WRITE_UINT32(INNOVATOR_INT_MASK_CLEAR, 1<<vector); #endif } void hal_interrupt_unmask(int vector) { #ifdef LATER CYG_ASSERT(vector <= CYGNUM_HAL_ISR_MAX && vector >= CYGNUM_HAL_ISR_MIN , "Invalid vector"); HAL_WRITE_UINT32(INNOVATOR_INT_MASK_SET, 1<<vector); #endif } void hal_interrupt_acknowledge(int vector) { #ifdef LATER CYG_ASSERT(vector <= CYGNUM_HAL_ISR_MAX && vector >= CYGNUM_HAL_ISR_MIN , "Invalid vector"); #endif } void hal_interrupt_configure(int vector, int level, int up) { #ifdef LATER CYG_ASSERT(vector <= CYGNUM_HAL_ISR_MAX && vector >= CYGNUM_HAL_ISR_MIN, "Invalid vector"); CYG_ASSERT(level || up, "Cannot do falling edge"); #endif } void hal_interrupt_set_level(int vector, int level) { #ifdef LATER cyg_uint32 reg; CYG_ASSERT(vector <= CYGNUM_HAL_ISR_MAX && vector >= CYGNUM_HAL_ISR_MIN, "Invalid vector"); CYG_ASSERT(level <= 63 && level >= 0, "Invalid level"); HAL_READ_UINT32(INNOVATOR_INT_PRIORITY_0+4*vector, reg); reg &= ~INNOVATOR_INT_PRIORITY_LVL_mask; reg |= (level & INNOVATOR_INT_PRIORITY_LVL_mask); HAL_WRITE_UINT32(INNOVATOR_INT_PRIORITY_0+4*vector, reg); #endif } #include CYGHWR_MEMORY_LAYOUT_H typedef void code_fun(void); void innovator_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; }
Go to most recent revision | Compare with Previous | Blame | View Log