/* * BF561 memory map * * Copyright 2004-2009 Analog Devices Inc. * Licensed under the GPL-2 or later. */ #ifndef __BFIN_MACH_MEM_MAP_H__ #define __BFIN_MACH_MEM_MAP_H__ #ifndef __BFIN_MEM_MAP_H__ # error "do not include mach/mem_map.h directly -- use asm/mem_map.h" #endif /* Async Memory Banks */ #define ASYNC_BANK3_BASE 0x2C000000 /* Async Bank 3 */ #define ASYNC_BANK3_SIZE 0x04000000 /* 64M */ #define ASYNC_BANK2_BASE 0x28000000 /* Async Bank 2 */ #define ASYNC_BANK2_SIZE 0x04000000 /* 64M */ #define ASYNC_BANK1_BASE 0x24000000 /* Async Bank 1 */ #define ASYNC_BANK1_SIZE 0x04000000 /* 64M */ #define ASYNC_BANK0_BASE 0x20000000 /* Async Bank 0 */ #define ASYNC_BANK0_SIZE 0x04000000 /* 64M */ /* Boot ROM Memory */ #define BOOT_ROM_START 0xEF000000 #define BOOT_ROM_LENGTH 0x800 /* Level 1 Memory */ #ifdef CONFIG_BFIN_ICACHE #define BFIN_ICACHESIZE (16*1024) #else #define BFIN_ICACHESIZE (0*1024) #endif /* Memory Map for ADSP-BF561 processors */ #define COREA_L1_CODE_START 0xFFA00000 #define COREA_L1_DATA_A_START 0xFF800000 #define COREA_L1_DATA_B_START 0xFF900000 #define COREB_L1_CODE_START 0xFF600000 #define COREB_L1_DATA_A_START 0xFF400000 #define COREB_L1_DATA_B_START 0xFF500000 #define L1_CODE_START COREA_L1_CODE_START #define L1_DATA_A_START COREA_L1_DATA_A_START #define L1_DATA_B_START COREA_L1_DATA_B_START #define L1_CODE_LENGTH 0x4000 #ifdef CONFIG_BFIN_DCACHE #ifdef CONFIG_BFIN_DCACHE_BANKA #define DMEM_CNTR (ACACHE_BSRAM | ENDCPLB | PORT_PREF0) #define L1_DATA_A_LENGTH (0x8000 - 0x4000) #define L1_DATA_B_LENGTH 0x8000 #define BFIN_DCACHESIZE (16*1024) #define BFIN_DSUPBANKS 1 #else #define DMEM_CNTR (ACACHE_BCACHE | ENDCPLB | PORT_PREF0) #define L1_DATA_A_LENGTH (0x8000 - 0x4000) #define L1_DATA_B_LENGTH (0x8000 - 0x4000) #define BFIN_DCACHESIZE (32*1024) #define BFIN_DSUPBANKS 2 #endif #else #define DMEM_CNTR (ASRAM_BSRAM | ENDCPLB | PORT_PREF0) #define L1_DATA_A_LENGTH 0x8000 #define L1_DATA_B_LENGTH 0x8000 #define BFIN_DCACHESIZE (0*1024) #define BFIN_DSUPBANKS 0 #endif /*CONFIG_BFIN_DCACHE*/ /* * If we are in SMP mode, then the cache settings of Core B will match * the settings of Core A. If we aren't, then we assume Core B is not * using any cache. This allows the rest of the kernel to work with * the core in either mode as we are only loading user code into it and * it is the user's problem to make sure they aren't doing something * stupid there. * * Note that we treat the L1 code region as a contiguous blob to make * the rest of the kernel simpler. Easier to check one region than a * bunch of small ones. Again, possible misbehavior here is the fault * of the user -- don't try to use memory that doesn't exist. */ #ifdef CONFIG_SMP # define COREB_L1_CODE_LENGTH L1_CODE_LENGTH # define COREB_L1_DATA_A_LENGTH L1_DATA_A_LENGTH # define COREB_L1_DATA_B_LENGTH L1_DATA_B_LENGTH #else # define COREB_L1_CODE_LENGTH 0x14000 # define COREB_L1_DATA_A_LENGTH 0x8000 # define COREB_L1_DATA_B_LENGTH 0x8000 #endif /* Level 2 Memory */ #define L2_START 0xFEB00000 #define L2_LENGTH 0x20000 /* Scratch Pad Memory */ #define COREA_L1_SCRATCH_START 0xFFB00000 #define COREB_L1_SCRATCH_START 0xFF700000 #ifdef CONFIG_SMP /* * The following macros both return the address of the PDA for the * current core. * * In its first safe (and hairy) form, the macro neither clobbers any * register aside of the output Preg, nor uses the stack, since it * could be called with an invalid stack pointer, or the current stack * space being uncovered by any CPLB (e.g. early exception handling). * * The constraints on the second form are a bit relaxed, and the code * is allowed to use the specified Dreg for determining the PDA * address to be returned into Preg. */ # define GET_PDA_SAFE(preg) \ preg.l = lo(DSPID); \ preg.h = hi(DSPID); \ preg = [preg]; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ preg = preg << 2; \ if cc jump 2f; \ cc = preg == 0x0; \ preg.l = _cpu_pda; \ preg.h = _cpu_pda; \ if !cc jump 3f; \ 1: \ /* preg = 0x0; */ \ cc = !cc; /* restore cc to 0 */ \ jump 4f; \ 2: \ cc = preg == 0x0; \ preg.l = _cpu_pda; \ preg.h = _cpu_pda; \ if cc jump 4f; \ /* preg = 0x1000000; */ \ cc = !cc; /* restore cc to 1 */ \ 3: \ preg = [preg]; \ 4: # define GET_PDA(preg, dreg) \ preg.l = lo(DSPID); \ preg.h = hi(DSPID); \ dreg = [preg]; \ preg.l = _cpu_pda; \ preg.h = _cpu_pda; \ cc = bittst(dreg, 0); \ if !cc jump 1f; \ preg = [preg]; \ 1: \ # define GET_CPUID(preg, dreg) \ preg.l = lo(DSPID); \ preg.h = hi(DSPID); \ dreg = [preg]; \ dreg = ROT dreg BY -1; \ dreg = CC; # ifndef __ASSEMBLY__ # include static inline unsigned long get_l1_scratch_start_cpu(int cpu) { return cpu ? COREB_L1_SCRATCH_START : COREA_L1_SCRATCH_START; } static inline unsigned long get_l1_code_start_cpu(int cpu) { return cpu ? COREB_L1_CODE_START : COREA_L1_CODE_START; } static inline unsigned long get_l1_data_a_start_cpu(int cpu) { return cpu ? COREB_L1_DATA_A_START : COREA_L1_DATA_A_START; } static inline unsigned long get_l1_data_b_start_cpu(int cpu) { return cpu ? COREB_L1_DATA_B_START : COREA_L1_DATA_B_START; } static inline unsigned long get_l1_scratch_start(void) { return get_l1_scratch_start_cpu(blackfin_core_id()); } static inline unsigned long get_l1_code_start(void) { return get_l1_code_start_cpu(blackfin_core_id()); } static inline unsigned long get_l1_data_a_start(void) { return get_l1_data_a_start_cpu(blackfin_core_id()); } static inline unsigned long get_l1_data_b_start(void) { return get_l1_data_b_start_cpu(blackfin_core_id()); } # endif /* __ASSEMBLY__ */ #endif /* CONFIG_SMP */ #endif