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https://github.com/AuxXxilium/linux_dsm_epyc7002.git
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c163fb38ca
The RISC-V port doesn't suport a nommu mode, so there is no reason to provide some code only under a CONFIG_MMU ifdef. Signed-off-by: Christoph Hellwig <hch@lst.de> Signed-off-by: Palmer Dabbelt <palmer@sifive.com>
302 lines
12 KiB
C
302 lines
12 KiB
C
/*
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* {read,write}{b,w,l,q} based on arch/arm64/include/asm/io.h
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* which was based on arch/arm/include/io.h
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*
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* Copyright (C) 1996-2000 Russell King
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* Copyright (C) 2012 ARM Ltd.
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* Copyright (C) 2014 Regents of the University of California
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation, version 2.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*/
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#ifndef _ASM_RISCV_IO_H
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#define _ASM_RISCV_IO_H
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#include <linux/types.h>
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extern void __iomem *ioremap(phys_addr_t offset, unsigned long size);
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/*
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* The RISC-V ISA doesn't yet specify how to query or modify PMAs, so we can't
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* change the properties of memory regions. This should be fixed by the
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* upcoming platform spec.
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*/
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#define ioremap_nocache(addr, size) ioremap((addr), (size))
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#define ioremap_wc(addr, size) ioremap((addr), (size))
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#define ioremap_wt(addr, size) ioremap((addr), (size))
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extern void iounmap(volatile void __iomem *addr);
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/* Generic IO read/write. These perform native-endian accesses. */
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#define __raw_writeb __raw_writeb
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static inline void __raw_writeb(u8 val, volatile void __iomem *addr)
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{
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asm volatile("sb %0, 0(%1)" : : "r" (val), "r" (addr));
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}
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#define __raw_writew __raw_writew
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static inline void __raw_writew(u16 val, volatile void __iomem *addr)
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{
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asm volatile("sh %0, 0(%1)" : : "r" (val), "r" (addr));
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}
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#define __raw_writel __raw_writel
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static inline void __raw_writel(u32 val, volatile void __iomem *addr)
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{
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asm volatile("sw %0, 0(%1)" : : "r" (val), "r" (addr));
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}
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#ifdef CONFIG_64BIT
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#define __raw_writeq __raw_writeq
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static inline void __raw_writeq(u64 val, volatile void __iomem *addr)
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{
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asm volatile("sd %0, 0(%1)" : : "r" (val), "r" (addr));
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}
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#endif
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#define __raw_readb __raw_readb
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static inline u8 __raw_readb(const volatile void __iomem *addr)
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{
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u8 val;
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asm volatile("lb %0, 0(%1)" : "=r" (val) : "r" (addr));
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return val;
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}
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#define __raw_readw __raw_readw
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static inline u16 __raw_readw(const volatile void __iomem *addr)
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{
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u16 val;
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asm volatile("lh %0, 0(%1)" : "=r" (val) : "r" (addr));
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return val;
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}
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#define __raw_readl __raw_readl
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static inline u32 __raw_readl(const volatile void __iomem *addr)
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{
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u32 val;
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asm volatile("lw %0, 0(%1)" : "=r" (val) : "r" (addr));
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return val;
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}
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#ifdef CONFIG_64BIT
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#define __raw_readq __raw_readq
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static inline u64 __raw_readq(const volatile void __iomem *addr)
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{
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u64 val;
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asm volatile("ld %0, 0(%1)" : "=r" (val) : "r" (addr));
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return val;
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}
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#endif
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/*
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* FIXME: I'm flip-flopping on whether or not we should keep this or enforce
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* the ordering with I/O on spinlocks like PowerPC does. The worry is that
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* drivers won't get this correct, but I also don't want to introduce a fence
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* into the lock code that otherwise only uses AMOs (and is essentially defined
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* by the ISA to be correct). For now I'm leaving this here: "o,w" is
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* sufficient to ensure that all writes to the device have completed before the
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* write to the spinlock is allowed to commit. I surmised this from reading
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* "ACQUIRES VS I/O ACCESSES" in memory-barriers.txt.
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*/
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#define mmiowb() __asm__ __volatile__ ("fence o,w" : : : "memory");
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/*
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* Unordered I/O memory access primitives. These are even more relaxed than
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* the relaxed versions, as they don't even order accesses between successive
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* operations to the I/O regions.
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*/
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#define readb_cpu(c) ({ u8 __r = __raw_readb(c); __r; })
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#define readw_cpu(c) ({ u16 __r = le16_to_cpu((__force __le16)__raw_readw(c)); __r; })
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#define readl_cpu(c) ({ u32 __r = le32_to_cpu((__force __le32)__raw_readl(c)); __r; })
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#define writeb_cpu(v,c) ((void)__raw_writeb((v),(c)))
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#define writew_cpu(v,c) ((void)__raw_writew((__force u16)cpu_to_le16(v),(c)))
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#define writel_cpu(v,c) ((void)__raw_writel((__force u32)cpu_to_le32(v),(c)))
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#ifdef CONFIG_64BIT
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#define readq_cpu(c) ({ u64 __r = le64_to_cpu((__force __le64)__raw_readq(c)); __r; })
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#define writeq_cpu(v,c) ((void)__raw_writeq((__force u64)cpu_to_le64(v),(c)))
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#endif
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/*
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* Relaxed I/O memory access primitives. These follow the Device memory
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* ordering rules but do not guarantee any ordering relative to Normal memory
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* accesses. These are defined to order the indicated access (either a read or
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* write) with all other I/O memory accesses. Since the platform specification
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* defines that all I/O regions are strongly ordered on channel 2, no explicit
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* fences are required to enforce this ordering.
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*/
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/* FIXME: These are now the same as asm-generic */
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#define __io_rbr() do {} while (0)
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#define __io_rar() do {} while (0)
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#define __io_rbw() do {} while (0)
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#define __io_raw() do {} while (0)
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#define readb_relaxed(c) ({ u8 __v; __io_rbr(); __v = readb_cpu(c); __io_rar(); __v; })
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#define readw_relaxed(c) ({ u16 __v; __io_rbr(); __v = readw_cpu(c); __io_rar(); __v; })
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#define readl_relaxed(c) ({ u32 __v; __io_rbr(); __v = readl_cpu(c); __io_rar(); __v; })
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#define writeb_relaxed(v,c) ({ __io_rbw(); writeb_cpu((v),(c)); __io_raw(); })
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#define writew_relaxed(v,c) ({ __io_rbw(); writew_cpu((v),(c)); __io_raw(); })
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#define writel_relaxed(v,c) ({ __io_rbw(); writel_cpu((v),(c)); __io_raw(); })
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#ifdef CONFIG_64BIT
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#define readq_relaxed(c) ({ u64 __v; __io_rbr(); __v = readq_cpu(c); __io_rar(); __v; })
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#define writeq_relaxed(v,c) ({ __io_rbw(); writeq_cpu((v),(c)); __io_raw(); })
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#endif
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/*
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* I/O memory access primitives. Reads are ordered relative to any
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* following Normal memory access. Writes are ordered relative to any prior
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* Normal memory access. The memory barriers here are necessary as RISC-V
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* doesn't define any ordering between the memory space and the I/O space.
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*/
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#define __io_br() do {} while (0)
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#define __io_ar() __asm__ __volatile__ ("fence i,r" : : : "memory");
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#define __io_bw() __asm__ __volatile__ ("fence w,o" : : : "memory");
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#define __io_aw() do {} while (0)
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#define readb(c) ({ u8 __v; __io_br(); __v = readb_cpu(c); __io_ar(); __v; })
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#define readw(c) ({ u16 __v; __io_br(); __v = readw_cpu(c); __io_ar(); __v; })
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#define readl(c) ({ u32 __v; __io_br(); __v = readl_cpu(c); __io_ar(); __v; })
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#define writeb(v,c) ({ __io_bw(); writeb_cpu((v),(c)); __io_aw(); })
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#define writew(v,c) ({ __io_bw(); writew_cpu((v),(c)); __io_aw(); })
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#define writel(v,c) ({ __io_bw(); writel_cpu((v),(c)); __io_aw(); })
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#ifdef CONFIG_64BIT
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#define readq(c) ({ u64 __v; __io_br(); __v = readq_cpu(c); __io_ar(); __v; })
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#define writeq(v,c) ({ __io_bw(); writeq_cpu((v),(c)); __io_aw(); })
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#endif
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/*
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* Emulation routines for the port-mapped IO space used by some PCI drivers.
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* These are defined as being "fully synchronous", but also "not guaranteed to
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* be fully ordered with respect to other memory and I/O operations". We're
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* going to be on the safe side here and just make them:
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* - Fully ordered WRT each other, by bracketing them with two fences. The
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* outer set contains both I/O so inX is ordered with outX, while the inner just
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* needs the type of the access (I for inX and O for outX).
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* - Ordered in the same manner as readX/writeX WRT memory by subsuming their
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* fences.
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* - Ordered WRT timer reads, so udelay and friends don't get elided by the
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* implementation.
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* Note that there is no way to actually enforce that outX is a non-posted
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* operation on RISC-V, but hopefully the timer ordering constraint is
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* sufficient to ensure this works sanely on controllers that support I/O
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* writes.
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*/
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#define __io_pbr() __asm__ __volatile__ ("fence io,i" : : : "memory");
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#define __io_par() __asm__ __volatile__ ("fence i,ior" : : : "memory");
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#define __io_pbw() __asm__ __volatile__ ("fence iow,o" : : : "memory");
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#define __io_paw() __asm__ __volatile__ ("fence o,io" : : : "memory");
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#define inb(c) ({ u8 __v; __io_pbr(); __v = readb_cpu((void*)(PCI_IOBASE + (c))); __io_par(); __v; })
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#define inw(c) ({ u16 __v; __io_pbr(); __v = readw_cpu((void*)(PCI_IOBASE + (c))); __io_par(); __v; })
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#define inl(c) ({ u32 __v; __io_pbr(); __v = readl_cpu((void*)(PCI_IOBASE + (c))); __io_par(); __v; })
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#define outb(v,c) ({ __io_pbw(); writeb_cpu((v),(void*)(PCI_IOBASE + (c))); __io_paw(); })
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#define outw(v,c) ({ __io_pbw(); writew_cpu((v),(void*)(PCI_IOBASE + (c))); __io_paw(); })
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#define outl(v,c) ({ __io_pbw(); writel_cpu((v),(void*)(PCI_IOBASE + (c))); __io_paw(); })
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#ifdef CONFIG_64BIT
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#define inq(c) ({ u64 __v; __io_pbr(); __v = readq_cpu((void*)(c)); __io_par(); __v; })
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#define outq(v,c) ({ __io_pbw(); writeq_cpu((v),(void*)(c)); __io_paw(); })
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#endif
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/*
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* Accesses from a single hart to a single I/O address must be ordered. This
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* allows us to use the raw read macros, but we still need to fence before and
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* after the block to ensure ordering WRT other macros. These are defined to
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* perform host-endian accesses so we use __raw instead of __cpu.
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*/
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#define __io_reads_ins(port, ctype, len, bfence, afence) \
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static inline void __ ## port ## len(const volatile void __iomem *addr, \
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void *buffer, \
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unsigned int count) \
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{ \
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bfence; \
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if (count) { \
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ctype *buf = buffer; \
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\
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do { \
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ctype x = __raw_read ## len(addr); \
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*buf++ = x; \
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} while (--count); \
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} \
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afence; \
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}
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#define __io_writes_outs(port, ctype, len, bfence, afence) \
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static inline void __ ## port ## len(volatile void __iomem *addr, \
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const void *buffer, \
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unsigned int count) \
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{ \
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bfence; \
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if (count) { \
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const ctype *buf = buffer; \
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\
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do { \
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__raw_write ## len(*buf++, addr); \
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} while (--count); \
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} \
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afence; \
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}
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__io_reads_ins(reads, u8, b, __io_br(), __io_ar())
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__io_reads_ins(reads, u16, w, __io_br(), __io_ar())
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__io_reads_ins(reads, u32, l, __io_br(), __io_ar())
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#define readsb(addr, buffer, count) __readsb(addr, buffer, count)
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#define readsw(addr, buffer, count) __readsw(addr, buffer, count)
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#define readsl(addr, buffer, count) __readsl(addr, buffer, count)
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__io_reads_ins(ins, u8, b, __io_pbr(), __io_par())
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__io_reads_ins(ins, u16, w, __io_pbr(), __io_par())
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__io_reads_ins(ins, u32, l, __io_pbr(), __io_par())
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#define insb(addr, buffer, count) __insb((void __iomem *)(long)addr, buffer, count)
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#define insw(addr, buffer, count) __insw((void __iomem *)(long)addr, buffer, count)
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#define insl(addr, buffer, count) __insl((void __iomem *)(long)addr, buffer, count)
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__io_writes_outs(writes, u8, b, __io_bw(), __io_aw())
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__io_writes_outs(writes, u16, w, __io_bw(), __io_aw())
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__io_writes_outs(writes, u32, l, __io_bw(), __io_aw())
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#define writesb(addr, buffer, count) __writesb(addr, buffer, count)
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#define writesw(addr, buffer, count) __writesw(addr, buffer, count)
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#define writesl(addr, buffer, count) __writesl(addr, buffer, count)
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__io_writes_outs(outs, u8, b, __io_pbw(), __io_paw())
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__io_writes_outs(outs, u16, w, __io_pbw(), __io_paw())
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__io_writes_outs(outs, u32, l, __io_pbw(), __io_paw())
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#define outsb(addr, buffer, count) __outsb((void __iomem *)(long)addr, buffer, count)
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#define outsw(addr, buffer, count) __outsw((void __iomem *)(long)addr, buffer, count)
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#define outsl(addr, buffer, count) __outsl((void __iomem *)(long)addr, buffer, count)
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#ifdef CONFIG_64BIT
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__io_reads_ins(reads, u64, q, __io_br(), __io_ar())
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#define readsq(addr, buffer, count) __readsq(addr, buffer, count)
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__io_reads_ins(ins, u64, q, __io_pbr(), __io_par())
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#define insq(addr, buffer, count) __insq((void __iomem *)addr, buffer, count)
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__io_writes_outs(writes, u64, q, __io_bw(), __io_aw())
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#define writesq(addr, buffer, count) __writesq(addr, buffer, count)
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__io_writes_outs(outs, u64, q, __io_pbr(), __io_paw())
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#define outsq(addr, buffer, count) __outsq((void __iomem *)addr, buffer, count)
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#endif
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#include <asm-generic/io.h>
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#endif /* _ASM_RISCV_IO_H */
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