#ifndef __ALPHA_LCA__H__ #define __ALPHA_LCA__H__ #include #include /* * Low Cost Alpha (LCA) definitions (these apply to 21066 and 21068, * for example). * * This file is based on: * * DECchip 21066 and DECchip 21068 Alpha AXP Microprocessors * Hardware Reference Manual; Digital Equipment Corp.; May 1994; * Maynard, MA; Order Number: EC-N2681-71. */ /* * NOTE: The LCA uses a Host Address Extension (HAE) register to access * PCI addresses that are beyond the first 27 bits of address * space. Updating the HAE requires an external cycle (and * a memory barrier), which tends to be slow. Instead of updating * it on each sparse memory access, we keep the current HAE value * cached in variable cache_hae. Only if the cached HAE differs * from the desired HAE value do we actually updated HAE register. * The HAE register is preserved by the interrupt handler entry/exit * code, so this scheme works even in the presence of interrupts. * * Dense memory space doesn't require the HAE, but is restricted to * aligned 32 and 64 bit accesses. Special Cycle and Interrupt * Acknowledge cycles may also require the use of the HAE. The LCA * limits I/O address space to the bottom 24 bits of address space, * but this easily covers the 16 bit ISA I/O address space. */ /* * NOTE 2! The memory operations do not set any memory barriers, as * it's not needed for cases like a frame buffer that is essentially * memory-like. You need to do them by hand if the operations depend * on ordering. * * Similarly, the port I/O operations do a "mb" only after a write * operation: if an mb is needed before (as in the case of doing * memory mapped I/O first, and then a port I/O operation to the same * device), it needs to be done by hand. * * After the above has bitten me 100 times, I'll give up and just do * the mb all the time, but right now I'm hoping this will work out. * Avoiding mb's may potentially be a noticeable speed improvement, * but I can't honestly say I've tested it. * * Handling interrupts that need to do mb's to synchronize to * non-interrupts is another fun race area. Don't do it (because if * you do, I'll have to do *everything* with interrupts disabled, * ugh). */ /* * Memory Controller registers: */ #define LCA_MEM_BCR0 (IDENT_ADDR + 0x120000000UL) #define LCA_MEM_BCR1 (IDENT_ADDR + 0x120000008UL) #define LCA_MEM_BCR2 (IDENT_ADDR + 0x120000010UL) #define LCA_MEM_BCR3 (IDENT_ADDR + 0x120000018UL) #define LCA_MEM_BMR0 (IDENT_ADDR + 0x120000020UL) #define LCA_MEM_BMR1 (IDENT_ADDR + 0x120000028UL) #define LCA_MEM_BMR2 (IDENT_ADDR + 0x120000030UL) #define LCA_MEM_BMR3 (IDENT_ADDR + 0x120000038UL) #define LCA_MEM_BTR0 (IDENT_ADDR + 0x120000040UL) #define LCA_MEM_BTR1 (IDENT_ADDR + 0x120000048UL) #define LCA_MEM_BTR2 (IDENT_ADDR + 0x120000050UL) #define LCA_MEM_BTR3 (IDENT_ADDR + 0x120000058UL) #define LCA_MEM_GTR (IDENT_ADDR + 0x120000060UL) #define LCA_MEM_ESR (IDENT_ADDR + 0x120000068UL) #define LCA_MEM_EAR (IDENT_ADDR + 0x120000070UL) #define LCA_MEM_CAR (IDENT_ADDR + 0x120000078UL) #define LCA_MEM_VGR (IDENT_ADDR + 0x120000080UL) #define LCA_MEM_PLM (IDENT_ADDR + 0x120000088UL) #define LCA_MEM_FOR (IDENT_ADDR + 0x120000090UL) /* * I/O Controller registers: */ #define LCA_IOC_HAE (IDENT_ADDR + 0x180000000UL) #define LCA_IOC_CONF (IDENT_ADDR + 0x180000020UL) #define LCA_IOC_STAT0 (IDENT_ADDR + 0x180000040UL) #define LCA_IOC_STAT1 (IDENT_ADDR + 0x180000060UL) #define LCA_IOC_TBIA (IDENT_ADDR + 0x180000080UL) #define LCA_IOC_TB_ENA (IDENT_ADDR + 0x1800000a0UL) #define LCA_IOC_SFT_RST (IDENT_ADDR + 0x1800000c0UL) #define LCA_IOC_PAR_DIS (IDENT_ADDR + 0x1800000e0UL) #define LCA_IOC_W_BASE0 (IDENT_ADDR + 0x180000100UL) #define LCA_IOC_W_BASE1 (IDENT_ADDR + 0x180000120UL) #define LCA_IOC_W_MASK0 (IDENT_ADDR + 0x180000140UL) #define LCA_IOC_W_MASK1 (IDENT_ADDR + 0x180000160UL) #define LCA_IOC_T_BASE0 (IDENT_ADDR + 0x180000180UL) #define LCA_IOC_T_BASE1 (IDENT_ADDR + 0x1800001a0UL) #define LCA_IOC_TB_TAG0 (IDENT_ADDR + 0x188000000UL) #define LCA_IOC_TB_TAG1 (IDENT_ADDR + 0x188000020UL) #define LCA_IOC_TB_TAG2 (IDENT_ADDR + 0x188000040UL) #define LCA_IOC_TB_TAG3 (IDENT_ADDR + 0x188000060UL) #define LCA_IOC_TB_TAG4 (IDENT_ADDR + 0x188000070UL) #define LCA_IOC_TB_TAG5 (IDENT_ADDR + 0x1880000a0UL) #define LCA_IOC_TB_TAG6 (IDENT_ADDR + 0x1880000c0UL) #define LCA_IOC_TB_TAG7 (IDENT_ADDR + 0x1880000e0UL) /* * Memory spaces: */ #define LCA_IACK_SC (IDENT_ADDR + 0x1a0000000UL) #define LCA_CONF (IDENT_ADDR + 0x1e0000000UL) #define LCA_IO (IDENT_ADDR + 0x1c0000000UL) #define LCA_SPARSE_MEM (IDENT_ADDR + 0x200000000UL) #define LCA_DENSE_MEM (IDENT_ADDR + 0x300000000UL) /* * Bit definitions for I/O Controller status register 0: */ #define LCA_IOC_STAT0_CMD 0xf #define LCA_IOC_STAT0_ERR (1<<4) #define LCA_IOC_STAT0_LOST (1<<5) #define LCA_IOC_STAT0_THIT (1<<6) #define LCA_IOC_STAT0_TREF (1<<7) #define LCA_IOC_STAT0_CODE_SHIFT 8 #define LCA_IOC_STAT0_CODE_MASK 0x7 #define LCA_IOC_STAT0_P_NBR_SHIFT 13 #define LCA_IOC_STAT0_P_NBR_MASK 0x7ffff #define LCA_HAE_ADDRESS LCA_IOC_HAE /* LCA PMR Power Management register defines */ #define LCA_PMR_ADDR (IDENT_ADDR + 0x120000098UL) #define LCA_PMR_PDIV 0x7 /* Primary clock divisor */ #define LCA_PMR_ODIV 0x38 /* Override clock divisor */ #define LCA_PMR_INTO 0x40 /* Interrupt override */ #define LCA_PMR_DMAO 0x80 /* DMA override */ #define LCA_PMR_OCCEB 0xffff0000L /* Override cycle counter - even bits */ #define LCA_PMR_OCCOB 0xffff000000000000L /* Override cycle counter - even bits */ #define LCA_PMR_PRIMARY_MASK 0xfffffffffffffff8 /* LCA PMR Macros */ #define LCA_READ_PMR (*(volatile unsigned long *)LCA_PMR_ADDR) #define LCA_WRITE_PMR(d) (*((volatile unsigned long *)LCA_PMR_ADDR) = (d)) #define LCA_GET_PRIMARY(r) ((r) & LCA_PMR_PDIV) #define LCA_GET_OVERRIDE(r) (((r) >> 3) & LCA_PMR_PDIV) #define LCA_SET_PRIMARY_CLOCK(r, c) ((r) = (((r) & LCA_PMR_PRIMARY_MASK)|(c))) /* LCA PMR Divisor values */ #define LCA_PMR_DIV_1 0x0 #define LCA_PMR_DIV_1_5 0x1 #define LCA_PMR_DIV_2 0x2 #define LCA_PMR_DIV_4 0x3 #define LCA_PMR_DIV_8 0x4 #define LCA_PMR_DIV_16 0x5 #define LCA_PMR_DIV_MIN DIV_1 #define LCA_PMR_DIV_MAX DIV_16 /* * Data structure for handling LCA machine checks. Correctable errors * result in a short logout frame, uncorrectable ones in a long one. */ struct el_lca_mcheck_short { struct el_common h; /* common logout header */ unsigned long esr; /* error-status register */ unsigned long ear; /* error-address register */ unsigned long dc_stat; /* dcache status register */ unsigned long ioc_stat0; /* I/O controller status register 0 */ unsigned long ioc_stat1; /* I/O controller status register 1 */ }; struct el_lca_mcheck_long { struct el_common h; /* common logout header */ unsigned long pt[31]; /* PAL temps */ unsigned long exc_addr; /* exception address */ unsigned long pad1[3]; unsigned long pal_base; /* PALcode base address */ unsigned long hier; /* hw interrupt enable */ unsigned long hirr; /* hw interrupt request */ unsigned long mm_csr; /* MMU control & status */ unsigned long dc_stat; /* data cache status */ unsigned long dc_addr; /* data cache addr register */ unsigned long abox_ctl; /* address box control register */ unsigned long esr; /* error status register */ unsigned long ear; /* error address register */ unsigned long car; /* cache control register */ unsigned long ioc_stat0; /* I/O controller status register 0 */ unsigned long ioc_stat1; /* I/O controller status register 1 */ unsigned long va; /* virtual address register */ }; union el_lca { struct el_common * c; struct el_lca_mcheck_long * l; struct el_lca_mcheck_short * s; }; #ifdef __KERNEL__ #ifndef __EXTERN_INLINE #define __EXTERN_INLINE extern inline #define __IO_EXTERN_INLINE #endif /* * I/O functions: * * Unlike Jensen, the Noname machines have no concept of local * I/O---everything goes over the PCI bus. * * There is plenty room for optimization here. In particular, * the Alpha's insb/insw/extb/extw should be useful in moving * data to/from the right byte-lanes. */ #define vip volatile int * #define vuip volatile unsigned int * #define vulp volatile unsigned long * __EXTERN_INLINE unsigned int lca_inb(unsigned long addr) { long result = *(vip) ((addr << 5) + LCA_IO + 0x00); return __kernel_extbl(result, addr & 3); } __EXTERN_INLINE void lca_outb(unsigned char b, unsigned long addr) { unsigned long w; w = __kernel_insbl(b, addr & 3); *(vuip) ((addr << 5) + LCA_IO + 0x00) = w; mb(); } __EXTERN_INLINE unsigned int lca_inw(unsigned long addr) { long result = *(vip) ((addr << 5) + LCA_IO + 0x08); return __kernel_extwl(result, addr & 3); } __EXTERN_INLINE void lca_outw(unsigned short b, unsigned long addr) { unsigned long w; w = __kernel_inswl(b, addr & 3); *(vuip) ((addr << 5) + LCA_IO + 0x08) = w; mb(); } __EXTERN_INLINE unsigned int lca_inl(unsigned long addr) { return *(vuip) ((addr << 5) + LCA_IO + 0x18); } __EXTERN_INLINE void lca_outl(unsigned int b, unsigned long addr) { *(vuip) ((addr << 5) + LCA_IO + 0x18) = b; mb(); } /* * Memory functions. 64-bit and 32-bit accesses are done through * dense memory space, everything else through sparse space. */ __EXTERN_INLINE unsigned long lca_readb(unsigned long addr) { unsigned long result, msb; addr -= LCA_DENSE_MEM; if (addr >= (1UL << 24)) { msb = addr & 0xf8000000; addr -= msb; set_hae(msb); } result = *(vip) ((addr << 5) + LCA_SPARSE_MEM + 0x00); return __kernel_extbl(result, addr & 3); } __EXTERN_INLINE unsigned long lca_readw(unsigned long addr) { unsigned long result, msb; addr -= LCA_DENSE_MEM; if (addr >= (1UL << 24)) { msb = addr & 0xf8000000; addr -= msb; set_hae(msb); } result = *(vip) ((addr << 5) + LCA_SPARSE_MEM + 0x08); return __kernel_extwl(result, addr & 3); } __EXTERN_INLINE unsigned long lca_readl(unsigned long addr) { return *(vuip)addr; } __EXTERN_INLINE unsigned long lca_readq(unsigned long addr) { return *(vulp)addr; } __EXTERN_INLINE void lca_writeb(unsigned char b, unsigned long addr) { unsigned long msb; unsigned long w; addr -= LCA_DENSE_MEM; if (addr >= (1UL << 24)) { msb = addr & 0xf8000000; addr -= msb; set_hae(msb); } w = __kernel_insbl(b, addr & 3); *(vuip) ((addr << 5) + LCA_SPARSE_MEM + 0x00) = w; } __EXTERN_INLINE void lca_writew(unsigned short b, unsigned long addr) { unsigned long msb; unsigned long w; addr -= LCA_DENSE_MEM; if (addr >= (1UL << 24)) { msb = addr & 0xf8000000; addr -= msb; set_hae(msb); } w = __kernel_inswl(b, addr & 3); *(vuip) ((addr << 5) + LCA_SPARSE_MEM + 0x08) = w; } __EXTERN_INLINE void lca_writel(unsigned int b, unsigned long addr) { *(vuip)addr = b; } __EXTERN_INLINE void lca_writeq(unsigned long b, unsigned long addr) { *(vulp)addr = b; } __EXTERN_INLINE unsigned long lca_ioremap(unsigned long addr) { return addr + LCA_DENSE_MEM; } __EXTERN_INLINE int lca_is_ioaddr(unsigned long addr) { return addr >= IDENT_ADDR + 0x120000000UL; } #undef vip #undef vuip #undef vulp #ifdef __WANT_IO_DEF #define __inb(p) lca_inb((unsigned long)(p)) #define __inw(p) lca_inw((unsigned long)(p)) #define __inl(p) lca_inl((unsigned long)(p)) #define __outb(x,p) lca_outb((x),(unsigned long)(p)) #define __outw(x,p) lca_outw((x),(unsigned long)(p)) #define __outl(x,p) lca_outl((x),(unsigned long)(p)) #define __readb(a) lca_readb((unsigned long)(a)) #define __readw(a) lca_readw((unsigned long)(a)) #define __readl(a) lca_readl((unsigned long)(a)) #define __readq(a) lca_readq((unsigned long)(a)) #define __writeb(x,a) lca_writeb((x),(unsigned long)(a)) #define __writew(x,a) lca_writew((x),(unsigned long)(a)) #define __writel(x,a) lca_writel((x),(unsigned long)(a)) #define __writeq(x,a) lca_writeq((x),(unsigned long)(a)) #define __ioremap(a) lca_ioremap((unsigned long)(a)) #define __is_ioaddr(a) lca_is_ioaddr((unsigned long)(a)) #define __raw_readl(a) __readl(a) #define __raw_readq(a) __readq(a) #define __raw_writel(v,a) __writel((v),(a)) #define __raw_writeq(v,a) __writeq((v),(a)) #endif /* __WANT_IO_DEF */ #ifdef __IO_EXTERN_INLINE #undef __EXTERN_INLINE #undef __IO_EXTERN_INLINE #endif #endif /* __KERNEL__ */ #endif /* __ALPHA_LCA__H__ */