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//========================================================================== // // nano_misc.c // // HAL misc board support code for StrongARM SA1110/nanoEngine // //========================================================================== // ####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, 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., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, 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 v2. // // This exception does not invalidate any other reasons why a work based // on this file might be covered by the GNU General Public License. // ------------------------------------------- // ####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: hmt // Travis C. Furrer <furrer@mit.edu> // Date: 2001-02-12 // 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/hal_sa11x0.h> // Hardware definitions #include <cyg/hal/nano.h> // Platform specifics #include <cyg/infra/diag.h> // diag_printf // All the MM table layout is here: #include <cyg/hal/hal_mm.h> #ifdef CYGPKG_IO_PCI cyg_uint32 cyg_pci_window_real_base = 0; #endif #include <string.h> // memset void hal_mmu_init(void) { unsigned long ttb_base = SA11X0_RAM_BANK0_BASE + 0x4000; unsigned long i; #ifdef CYG_HAL_STARTUP_ROM // SDRAM Memory Sizing: // // The board can have 4 memory configurations: // // * One 8Mb device on SDCS0 (with gaps <= A11 N/C in 8Mb devices) // * Two 8Mb devices, SDCS0,SDCS1 (with gaps) making 16Mb // * One 16Mb device on SDCS0 // * Two 16Mb devices on SDCS0,SDCS1 making 32Mb // // Gaps: the SDRAM setup and wiring are the same for both 8Mb and 16Mb // devices. A11 of the SDRAM's addressing is not connected when 8Mb // devices are installed; the 8Mb device occupies 16Mb of space. A11 // on the SDRAM is the most significant bit below the two bank-select // bits, there are 4 banks each occupying 4Mb, so therefore in "real // money" it has the value 2Mb. // // SDCS0 maps to the 128Mb area 0xC00 Mb (0xC00000000) // SDCS1 maps to the 128Mb area 0xC80 Mb (0xC80000000) // // So therefore, if there are two 8Mb devices installed, we have memory // in these ranges: // // 0xC0000000...0xC01FFFFF // 0xC0400000...0xC05FFFFF // 0xC0800000...0xC09FFFFF // 0xC0C00000...0xC0DFFFFF // // 0xC8000000...0xC81FFFFF // 0xC8400000...0xC85FFFFF // 0xC8800000...0xC89FFFFF // 0xC8C00000...0xC8DFFFFF // // This function is currently executing on a stack in real memory // addresses, somewhere in that initial range 0xC0000000...0xC01FFFFF, // so we can probe other related addresses to discover how much memory // we really have, and then set up the Memory Map accordingly. typedef volatile cyg_uint32 *mptr; // for memory access typedef cyg_uint32 aptr; // for arithmetic volatile int testmem[4] = {0}; // on my stack, ergo in base memory // Pointers to test memory, and into the possible gap: mptr basep = &testmem[0]; mptr basep2 = &testmem[1]; mptr gapp = (mptr)((2 * SZ_1M) | (aptr)basep); // And just look at any pair of words to discover whether there is // a 2nd device there. mptr dev2p = (mptr)((0xC80u * SZ_1M) | (aptr)basep); mptr dev2p2 = (mptr)(4 + (aptr)dev2p); // This is a pointer to where hal_dram_size is in physical memory, // since memory mapping is not yet set up: int *p_hdsize = (int *)((aptr)(&hal_dram_size) | (0xC00u *SZ_1M)); int *p_hdtype = (int *)((aptr)(&hal_dram_type) | (0xC00u *SZ_1M)); *p_hdsize = 0; // Initialize it to a bogus value here. *p_hdtype = 0x0108; // Initialize it to a bogus value here. // Equivalent of asserts for our assumptions, but too early to use // CYG_ASSERT( ..., "basep not in bank0 of device 0, lower half" ); if ( 0xC0000000u >= (aptr)basep ) { *p_hdtype |= 1 << 16; // flag an error code goto breakout; } if ( 0xC0200000u < (aptr)basep ) { *p_hdtype |= 2 << 16; goto breakout; } // First confirm that the technique works for memory that's // definitely there! *basep = 0x55667711; *basep2 = 0xCC33AA44; if ( 0x55667711 != *basep || 0xCC33AA44 != *basep2 ) { *p_hdtype |= 10 << 16; goto breakout; } // Now test writing to the gap... *gapp = 0xDD2288BB; if ( 0xCC33AA44 != *basep2 ) { // Should not be corrupted whatever *p_hdtype |= 20 << 16; goto breakout; } if ( 0xDD2288BB != *basep && 0x55667711 != *basep ) { // Should be one of those *p_hdtype |= 30 << 16; goto breakout; } if (0xDD2288BB == *basep) *p_hdtype = 8; // Lower byte is SDRAM size in Mb. else { // it could be 16Mb or 32Mb: basep2 = (mptr)((16 * SZ_1M) | (aptr)basep); *basep = 0xFF11AA00; *basep2 = 0x33557799; // (intersperse some other activity) testmem[2] += testmem[3]; if ( 0xFF11AA00 != *basep && 0x33557799 != *basep ) { // Should be one of those *p_hdtype |= 40 << 16; goto breakout; } *p_hdtype = (0xFF11AA00 == *basep) ? 32 : 16; } // Now test whether dev2p stores data: *dev2p = 0x11224488; *dev2p2 = 0x77BBDDEE; // (intersperse some other activity) testmem[2] += testmem[3]; *p_hdtype |= ((( 0x11224488 == *dev2p ) && (0x77BBDDEE == *dev2p2 )) ? 0x200 : 0x100); // Next byte is devcount. breakout: // NB: *p_hdtype is carefully crafted to make a system with an error // detected above default to a single 8Mb device in all the ensuing // setup. // So now we should know: *p_hdsize = (0xff & ((*p_hdtype) >> 8)) * (0xff & *p_hdtype) * SZ_1M; /* * 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_DACR_DEFAULT; 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, 0x500, 32, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* Boot flash ROMspace */ #endif // CYG_HAL_STARTUP_ROM - ROM start only // We can do the mapping of the other stuff (NOT RAM) in RAM startup OK. X_ARM_MMU_SECTION(0x180, 0x180, 16, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* Ethernet Adaptor */ X_ARM_MMU_SECTION(0x400, 0x400, 128, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* External IO Mux */ X_ARM_MMU_SECTION(0x480, 0x480, 128, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* External IO NonMux */ #ifdef CYG_HAL_STARTUP_ROM // ROM start only X_ARM_MMU_SECTION(0x800, 0x800, 0x400, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* StrongARM(R) Registers */ // X_ARM_MMU_SECTION(0xC00, 0, 32, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0,... */ // X_ARM_MMU_SECTION(0xC00, 0xC00, 32, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0,... */ if ( (*p_hdtype & 32) ) { // Then they are 32Mb devices - KISS: X_ARM_MMU_SECTION(0xC00, 0, 32, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ X_ARM_MMU_SECTION(0xC00, 0xC00, 32, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ if ( 0x200 & *p_hdtype ) { // Got the 2nd device? X_ARM_MMU_SECTION(0xC80, 32, 32, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ X_ARM_MMU_SECTION(0xC80, 0xC80, 32, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ } } else if ( (*p_hdtype & 16) ) { // Then they are 16Mb devices - KISS: X_ARM_MMU_SECTION(0xC00, 0, 16, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ X_ARM_MMU_SECTION(0xC00, 0xC00, 16, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ if ( 0x200 & *p_hdtype ) { // Got the 2nd device? X_ARM_MMU_SECTION(0xC80, 16, 16, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ X_ARM_MMU_SECTION(0xC80, 0xC80, 16, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ } } else { // Then they are 8Mb devices, complicated: X_ARM_MMU_SECTION(0xC00, 0, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ X_ARM_MMU_SECTION(0xC04, 2, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ X_ARM_MMU_SECTION(0xC08, 4, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ X_ARM_MMU_SECTION(0xC0C, 6, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ // Next slot is 16Mb of space, with 2Mb gaps per 4Mb. X_ARM_MMU_SECTION(0xC00, 0xC00, 16, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 0 */ if ( 0x200 & *p_hdtype ) { // Got the 2nd device? X_ARM_MMU_SECTION(0xC80, 8, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ X_ARM_MMU_SECTION(0xC84, 10, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ X_ARM_MMU_SECTION(0xC88, 12, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ X_ARM_MMU_SECTION(0xC8C, 14, 2, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ // Next slot is also 16Mb of space, with 2Mb gaps per 4Mb. X_ARM_MMU_SECTION(0xC80, 0xC80, 16, ARM_UNCACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* DRAM Bank 1 */ } } #endif // CYG_HAL_STARTUP_ROM - ROM start only #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_NANO_PCI_MEM_MAP_BASE >> 20; i < ((CYGHWR_HAL_ARM_NANO_PCI_MEM_MAP_BASE+CYGHWR_HAL_ARM_NANO_PCI_MEM_MAP_SIZE) >> 20); i++) { #ifndef CYG_HAL_STARTUP_ROM // RAM start - common code below must go via uncached pointer int *p_hdsize = (int *)(((cyg_uint32)&hal_dram_size) | (0xC00u *SZ_1M)); #endif // not CYG_HAL_STARTUP_ROM - RAM start only // Find the actual real address as above if already mapped: cyg_uint32 phys = hal_virt_to_phys_address( ((cyg_uint32)i) << 20 ); int j = phys >> 20; if ( ! ( 0xc00 < j && j < 0xe00 ) ) { // Not in physical SDRAM so yet mapped - so steal some from the main area. int k = (*p_hdsize) >> 20; // Top MegaByte k--; phys = hal_virt_to_phys_address( ((cyg_uint32)k) << 20 ); j = phys >> 20; CYG_ASSERT( 0xc00 < j && j < 0xe00, "Top Mb physical address not in SDRAM" ); (*p_hdsize) = (k << 20); // We just stole 1Mb. *(ARM_MMU_FIRST_LEVEL_DESCRIPTOR_ADDRESS(ttb_base, k)) = 0; // smash the old entry } CYG_ASSERT( 0xc00 < j && j < 0xe00, "PCI physical address not in SDRAM" ); ARM_MMU_SECTION(ttb_base, j, i, ARM_UNCACHEABLE, ARM_UNBUFFERABLE, ARM_ACCESS_PERM_RW_RW); } #endif #ifdef CYG_HAL_STARTUP_ROM X_ARM_MMU_SECTION(0xE00, 0xE00, 128, ARM_CACHEABLE, ARM_BUFFERABLE, ARM_ACCESS_PERM_RW_RW); /* Zeros (Cache Clean) Bank */ #endif // CYG_HAL_STARTUP_ROM - ROM start only // All done, phew! } // // Platform specific initialization // void plf_hardware_init(void) { // RAM startup only - rewrite relevent bits depending on config #ifndef CYG_HAL_STARTUP_ROM HAL_DCACHE_SYNC(); // Force data out hal_mmu_init(); // This works on real addresses only HAL_DCACHE_INVALIDATE_ALL(); // Flush TLBs: make new mmu state effective #endif // ! CYG_HAL_STARTUP_ROM - RAM start only #ifdef CYGPKG_IO_PCI cyg_pci_window_real_base = hal_virt_to_phys_address( CYGHWR_HAL_ARM_NANO_PCI_MEM_MAP_BASE ); #endif } #include CYGHWR_MEMORY_LAYOUT_H typedef void code_fun(void); void nano_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; } // // 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" ); CYG_ASSERT( 0 == (hal_dram_size & 0xfffff), "hal_dram_size not whole Mb" ); // 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; } // Also, we must check for the top of the heap having moved. This is // because the heap does not abut the top of memory. #ifdef CYGMEM_SECTION_heap1 else if ( regionend == ((cyg_uint8 *)CYGMEM_SECTION_heap1 + CYGMEM_SECTION_heap1_SIZE) ) { // hal_dram_size excludes the PCI window on this platform. if ( regionend > (cyg_uint8 *)CYGMEM_REGION_ram + hal_dram_size ) // Only report if the heap shrank; if it abuts RAMtop, the // previous test will have caught it already. If RAM enlarged, // but the heap did not abut RAMtop then there is likely // something in the way, so don't trample it. regionend = (cyg_uint8 *)CYGMEM_REGION_ram + hal_dram_size; } #endif return regionend; } // ------------------------------------------------------------------------ // EOF nano_misc.c