arch/arc/include/asm/io.h - platform/external/u-boot - Gitiles

 /* SPDX-License-Identifier: GPL-2.0+ */
 /*
  * Copyright (C) 2013-2014, 2020 Synopsys, Inc. All rights reserved.
  */

 #ifndef __ASM_ARC_IO_H
 #define __ASM_ARC_IO_H

 #include <linux/types.h>
 #include <asm/byteorder.h>

 /*
  * Compiler barrier. It prevents compiler from reordering instructions before
  * and after it. It doesn't prevent HW (CPU) from any reordering though.
  */
 #define __comp_b()		asm volatile("" : : : "memory")

 #ifdef __ARCHS__

 /*
  * ARCv2 based HS38 cores are in-order issue, but still weakly ordered
  * due to micro-arch buffering/queuing of load/store, cache hit vs. miss ...
  *
  * Explicit barrier provided by DMB instruction
  *  - Operand supports fine grained load/store/load+store semantics
  *  - Ensures that selected memory operation issued before it will complete
  *    before any subsequent memory operation of same type
  *  - DMB guarantees SMP as well as local barrier semantics
  *    (asm-generic/barrier.h ensures sane smp_*mb if not defined here, i.e.
  *    UP: barrier(), SMP: smp_*mb == *mb)
  *  - DSYNC provides DMB+completion_of_cache_bpu_maintenance_ops hence not needed
  *    in the general case. Plus it only provides full barrier.
  */

 #define mb()	asm volatile("dmb 3\n" : : : "memory")
 #define rmb()	asm volatile("dmb 1\n" : : : "memory")
 #define wmb()	asm volatile("dmb 2\n" : : : "memory")

 #else

 /*
  * ARCompact based cores (ARC700) only have SYNC instruction which is super
  * heavy weight as it flushes the pipeline as well.
  * There are no real SMP implementations of such cores.
  */

 #define mb()	asm volatile("sync\n" : : : "memory")
 #endif

 #ifdef __ARCHS__
 #define __iormb()		rmb()
 #define __iowmb()		wmb()
 #else
 #define __iormb()		__comp_b()
 #define __iowmb()		__comp_b()
 #endif

 static inline void sync(void)
 {
 	/* Not yet implemented */
 }

 /*
  * We must use 'volatile' in C-version read/write IO accessors implementation
  * to avoid merging several reads (writes) into one read (write), or optimizing
  * them out by compiler.
  * We must use compiler barriers before and after operation (read or write) so
  * it won't be reordered by compiler.
  */
 #define __arch_getb(a)		({ u8  __v; __comp_b(); __v = *(volatile u8  *)(a); __comp_b(); __v; })
 #define __arch_getw(a)		({ u16 __v; __comp_b(); __v = *(volatile u16 *)(a); __comp_b(); __v; })
 #define __arch_getl(a)		({ u32 __v; __comp_b(); __v = *(volatile u32 *)(a); __comp_b(); __v; })
 #define __arch_getq(a)		({ u64 __v; __comp_b(); __v = *(volatile u64 *)(a); __comp_b(); __v; })

 #define __arch_putb(v, a)	({ __comp_b(); *(volatile u8  *)(a) = (v); __comp_b(); })
 #define __arch_putw(v, a)	({ __comp_b(); *(volatile u16 *)(a) = (v); __comp_b(); })
 #define __arch_putl(v, a)	({ __comp_b(); *(volatile u32 *)(a) = (v); __comp_b(); })
 #define __arch_putq(v, a)	({ __comp_b(); *(volatile u64 *)(a) = (v); __comp_b(); })


 /*
  * We add memory barriers for __raw_readX / __raw_writeX accessors same way as
  * it is done for readX and writeX accessors as lots of U-boot driver uses
  * __raw_readX / __raw_writeX instead of proper accessor with barrier.
  */
 #define __raw_writeb(v, c)	({ __iowmb(); __arch_putb(v, c); })
 #define __raw_writew(v, c)	({ __iowmb(); __arch_putw(v, c); })
 #define __raw_writel(v, c)	({ __iowmb(); __arch_putl(v, c); })
 #define __raw_writeq(v, c)	({ __iowmb(); __arch_putq(v, c); })

 #define __raw_readb(c)		({ u8  __v = __arch_getb(c); __iormb(); __v; })
 #define __raw_readw(c)		({ u16 __v = __arch_getw(c); __iormb(); __v; })
 #define __raw_readl(c)		({ u32 __v = __arch_getl(c); __iormb(); __v; })
 #define __raw_readq(c)		({ u64 __v = __arch_getq(c); __iormb(); __v; })


 static inline void __raw_writesb(unsigned long addr, const void *data,
 				 int bytelen)
 {
 	u8 *buf = (uint8_t *)data;

 	__iowmb();

 	while (bytelen--)
 		__arch_putb(*buf++, addr);
 }

 static inline void __raw_writesw(unsigned long addr, const void *data,
 				 int wordlen)
 {
 	u16 *buf = (uint16_t *)data;

 	__iowmb();

 	while (wordlen--)
 		__arch_putw(*buf++, addr);
 }

 static inline void __raw_writesl(unsigned long addr, const void *data,
 				 int longlen)
 {
 	u32 *buf = (uint32_t *)data;

 	__iowmb();

 	while (longlen--)
 		__arch_putl(*buf++, addr);
 }

 static inline void __raw_readsb(unsigned long addr, void *data, int bytelen)
 {
 	u8 *buf = (uint8_t *)data;

 	while (bytelen--)
 		*buf++ = __arch_getb(addr);

 	__iormb();
 }

 static inline void __raw_readsw(unsigned long addr, void *data, int wordlen)
 {
 	u16 *buf = (uint16_t *)data;

 	while (wordlen--)
 		*buf++ = __arch_getw(addr);

 	__iormb();
 }

 static inline void __raw_readsl(unsigned long addr, void *data, int longlen)
 {
 	u32 *buf = (uint32_t *)data;

 	while (longlen--)
 		*buf++ = __arch_getl(addr);

 	__iormb();
 }

 /*
  * Relaxed I/O memory access primitives. These follow the Device memory
  * ordering rules but do not guarantee any ordering relative to Normal memory
  * accesses.
  */
 #define readb_relaxed(c)	({ u8  __r = __arch_getb(c); __r; })
 #define readw_relaxed(c)	({ u16 __r = le16_to_cpu((__force __le16)__arch_getw(c)); __r; })
 #define readl_relaxed(c)	({ u32 __r = le32_to_cpu((__force __le32)__arch_getl(c)); __r; })
 #define readq_relaxed(c)	({ u64 __r = le64_to_cpu((__force __le64)__arch_getq(c)); __r; })

 #define writeb_relaxed(v, c)	((void)__arch_putb((v), (c)))
 #define writew_relaxed(v, c)	((void)__arch_putw((__force u16)cpu_to_le16(v), (c)))
 #define writel_relaxed(v, c)	((void)__arch_putl((__force u32)cpu_to_le32(v), (c)))
 #define writeq_relaxed(v, c)	((void)__arch_putq((__force u64)cpu_to_le64(v), (c)))

 /*
  * MMIO can also get buffered/optimized in micro-arch, so barriers needed
  * Based on ARM model for the typical use case
  *
  *	<ST [DMA buffer]>
  *	<writel MMIO "go" reg>
  *  or:
  *	<readl MMIO "status" reg>
  *	<LD [DMA buffer]>
  *
  * http://lkml.kernel.org/r/20150622133656.GG1583@arm.com
  */
 #define readb(c)	({ u8  __v = readb_relaxed(c); __iormb(); __v; })
 #define readw(c)	({ u16 __v = readw_relaxed(c); __iormb(); __v; })
 #define readl(c)	({ u32 __v = readl_relaxed(c); __iormb(); __v; })
 #define readq(c)	({ u64 __v = readq_relaxed(c); __iormb(); __v; })

 #define writeb(v, c)	({ __iowmb(); writeb_relaxed(v, c); })
 #define writew(v, c)	({ __iowmb(); writew_relaxed(v, c); })
 #define writel(v, c)	({ __iowmb(); writel_relaxed(v, c); })
 #define writeq(v, c)	({ __iowmb(); writeq_relaxed(v, c); })

 #define out_arch(type, endian, a, v)	__raw_write##type(cpu_to_##endian(v), a)
 #define in_arch(type, endian, a)	endian##_to_cpu(__raw_read##type(a))

 #define out_le32(a, v)	out_arch(l, le32, a, v)
 #define out_le16(a, v)	out_arch(w, le16, a, v)

 #define in_le32(a)	in_arch(l, le32, a)
 #define in_le16(a)	in_arch(w, le16, a)

 #define out_be32(a, v)	out_arch(l, be32, a, v)
 #define out_be16(a, v)	out_arch(w, be16, a, v)

 #define in_be32(a)	in_arch(l, be32, a)
 #define in_be16(a)	in_arch(w, be16, a)

 #define out_8(a, v)	__raw_writeb(v, a)
 #define in_8(a)		__raw_readb(a)

 /*
  * Clear and set bits in one shot. These macros can be used to clear and
  * set multiple bits in a register using a single call. These macros can
  * also be used to set a multiple-bit bit pattern using a mask, by
  * specifying the mask in the 'clear' parameter and the new bit pattern
  * in the 'set' parameter.
  */

 #define clrbits(type, addr, clear) \
 	out_##type((addr), in_##type(addr) & ~(clear))

 #define setbits(type, addr, set) \
 	out_##type((addr), in_##type(addr) | (set))

 #define clrsetbits(type, addr, clear, set) \
 	out_##type((addr), (in_##type(addr) & ~(clear)) | (set))

 #define clrbits_be32(addr, clear) clrbits(be32, addr, clear)
 #define setbits_be32(addr, set) setbits(be32, addr, set)
 #define clrsetbits_be32(addr, clear, set) clrsetbits(be32, addr, clear, set)

 #define clrbits_le32(addr, clear) clrbits(le32, addr, clear)
 #define setbits_le32(addr, set) setbits(le32, addr, set)
 #define clrsetbits_le32(addr, clear, set) clrsetbits(le32, addr, clear, set)

 #define clrbits_be16(addr, clear) clrbits(be16, addr, clear)
 #define setbits_be16(addr, set) setbits(be16, addr, set)
 #define clrsetbits_be16(addr, clear, set) clrsetbits(be16, addr, clear, set)

 #define clrbits_le16(addr, clear) clrbits(le16, addr, clear)
 #define setbits_le16(addr, set) setbits(le16, addr, set)
 #define clrsetbits_le16(addr, clear, set) clrsetbits(le16, addr, clear, set)

 #define clrbits_8(addr, clear) clrbits(8, addr, clear)
 #define setbits_8(addr, set) setbits(8, addr, set)
 #define clrsetbits_8(addr, clear, set) clrsetbits(8, addr, clear, set)

 #include <asm-generic/io.h>

 #endif	/* __ASM_ARC_IO_H */
	/* SPDX-License-Identifier: GPL-2.0+ */
	/*
	* Copyright (C) 2013-2014, 2020 Synopsys, Inc. All rights reserved.
	*/

	#ifndef __ASM_ARC_IO_H
	#define __ASM_ARC_IO_H

	#include <linux/types.h>
	#include <asm/byteorder.h>

	/*
	* Compiler barrier. It prevents compiler from reordering instructions before
	* and after it. It doesn't prevent HW (CPU) from any reordering though.
	*/
	#define __comp_b() asm volatile("" : : : "memory")

	#ifdef __ARCHS__

	/*
	* ARCv2 based HS38 cores are in-order issue, but still weakly ordered
	* due to micro-arch buffering/queuing of load/store, cache hit vs. miss ...
	*
	* Explicit barrier provided by DMB instruction
	* - Operand supports fine grained load/store/load+store semantics
	* - Ensures that selected memory operation issued before it will complete
	* before any subsequent memory operation of same type
	* - DMB guarantees SMP as well as local barrier semantics
	* (asm-generic/barrier.h ensures sane smp_*mb if not defined here, i.e.
	* UP: barrier(), SMP: smp_mb == mb)
	* - DSYNC provides DMB+completion_of_cache_bpu_maintenance_ops hence not needed
	* in the general case. Plus it only provides full barrier.
	*/

	#define mb() asm volatile("dmb 3\n" : : : "memory")
	#define rmb() asm volatile("dmb 1\n" : : : "memory")
	#define wmb() asm volatile("dmb 2\n" : : : "memory")

	#else

	/*
	* ARCompact based cores (ARC700) only have SYNC instruction which is super
	* heavy weight as it flushes the pipeline as well.
	* There are no real SMP implementations of such cores.
	*/

	#define mb() asm volatile("sync\n" : : : "memory")
	#endif

	#ifdef __ARCHS__
	#define __iormb() rmb()
	#define __iowmb() wmb()
	#else
	#define __iormb() __comp_b()
	#define __iowmb() __comp_b()
	#endif

	static inline void sync(void)
	{
	/* Not yet implemented */
	}

	/*
	* We must use 'volatile' in C-version read/write IO accessors implementation
	* to avoid merging several reads (writes) into one read (write), or optimizing
	* them out by compiler.
	* We must use compiler barriers before and after operation (read or write) so
	* it won't be reordered by compiler.
	*/
	#define __arch_getb(a) ({ u8 __v; __comp_b(); __v = (volatile u8 )(a); __comp_b(); __v; })
	#define __arch_getw(a) ({ u16 __v; __comp_b(); __v = (volatile u16 )(a); __comp_b(); __v; })
	#define __arch_getl(a) ({ u32 __v; __comp_b(); __v = (volatile u32 )(a); __comp_b(); __v; })
	#define __arch_getq(a) ({ u64 __v; __comp_b(); __v = (volatile u64 )(a); __comp_b(); __v; })

	#define __arch_putb(v, a) ({ __comp_b(); (volatile u8 )(a) = (v); __comp_b(); })
	#define __arch_putw(v, a) ({ __comp_b(); (volatile u16 )(a) = (v); __comp_b(); })
	#define __arch_putl(v, a) ({ __comp_b(); (volatile u32 )(a) = (v); __comp_b(); })
	#define __arch_putq(v, a) ({ __comp_b(); (volatile u64 )(a) = (v); __comp_b(); })


	/*
	* We add memory barriers for __raw_readX / __raw_writeX accessors same way as
	* it is done for readX and writeX accessors as lots of U-boot driver uses
	* __raw_readX / __raw_writeX instead of proper accessor with barrier.
	*/
	#define __raw_writeb(v, c) ({ __iowmb(); __arch_putb(v, c); })
	#define __raw_writew(v, c) ({ __iowmb(); __arch_putw(v, c); })
	#define __raw_writel(v, c) ({ __iowmb(); __arch_putl(v, c); })
	#define __raw_writeq(v, c) ({ __iowmb(); __arch_putq(v, c); })

	#define __raw_readb(c) ({ u8 __v = __arch_getb(c); __iormb(); __v; })
	#define __raw_readw(c) ({ u16 __v = __arch_getw(c); __iormb(); __v; })
	#define __raw_readl(c) ({ u32 __v = __arch_getl(c); __iormb(); __v; })
	#define __raw_readq(c) ({ u64 __v = __arch_getq(c); __iormb(); __v; })


	static inline void __raw_writesb(unsigned long addr, const void *data,
	int bytelen)
	{
	u8 buf = (uint8_t )data;

	__iowmb();

	while (bytelen--)
	__arch_putb(*buf++, addr);
	}

	static inline void __raw_writesw(unsigned long addr, const void *data,
	int wordlen)
	{
	u16 buf = (uint16_t )data;

	__iowmb();

	while (wordlen--)
	__arch_putw(*buf++, addr);
	}

	static inline void __raw_writesl(unsigned long addr, const void *data,
	int longlen)
	{
	u32 buf = (uint32_t )data;

	__iowmb();

	while (longlen--)
	__arch_putl(*buf++, addr);
	}

	static inline void __raw_readsb(unsigned long addr, void *data, int bytelen)
	{
	u8 buf = (uint8_t )data;

	while (bytelen--)
	*buf++ = __arch_getb(addr);

	__iormb();
	}

	static inline void __raw_readsw(unsigned long addr, void *data, int wordlen)
	{
	u16 buf = (uint16_t )data;

	while (wordlen--)
	*buf++ = __arch_getw(addr);

	__iormb();
	}

	static inline void __raw_readsl(unsigned long addr, void *data, int longlen)
	{
	u32 buf = (uint32_t )data;

	while (longlen--)
	*buf++ = __arch_getl(addr);

	__iormb();
	}

	/*
	* Relaxed I/O memory access primitives. These follow the Device memory
	* ordering rules but do not guarantee any ordering relative to Normal memory
	* accesses.
	*/
	#define readb_relaxed(c) ({ u8 __r = __arch_getb(c); __r; })
	#define readw_relaxed(c) ({ u16 __r = le16_to_cpu((__force __le16)__arch_getw(c)); __r; })
	#define readl_relaxed(c) ({ u32 __r = le32_to_cpu((__force __le32)__arch_getl(c)); __r; })
	#define readq_relaxed(c) ({ u64 __r = le64_to_cpu((__force __le64)__arch_getq(c)); __r; })

	#define writeb_relaxed(v, c) ((void)__arch_putb((v), (c)))
	#define writew_relaxed(v, c) ((void)__arch_putw((__force u16)cpu_to_le16(v), (c)))
	#define writel_relaxed(v, c) ((void)__arch_putl((__force u32)cpu_to_le32(v), (c)))
	#define writeq_relaxed(v, c) ((void)__arch_putq((__force u64)cpu_to_le64(v), (c)))

	/*
	* MMIO can also get buffered/optimized in micro-arch, so barriers needed
	* Based on ARM model for the typical use case
	*
	* <ST [DMA buffer]>
	* <writel MMIO "go" reg>
	* or:
	* <readl MMIO "status" reg>
	* <LD [DMA buffer]>
	*
	* http://lkml.kernel.org/r/20150622133656.GG1583@arm.com
	*/
	#define readb(c) ({ u8 __v = readb_relaxed(c); __iormb(); __v; })
	#define readw(c) ({ u16 __v = readw_relaxed(c); __iormb(); __v; })
	#define readl(c) ({ u32 __v = readl_relaxed(c); __iormb(); __v; })
	#define readq(c) ({ u64 __v = readq_relaxed(c); __iormb(); __v; })

	#define writeb(v, c) ({ __iowmb(); writeb_relaxed(v, c); })
	#define writew(v, c) ({ __iowmb(); writew_relaxed(v, c); })
	#define writel(v, c) ({ __iowmb(); writel_relaxed(v, c); })
	#define writeq(v, c) ({ __iowmb(); writeq_relaxed(v, c); })

	#define out_arch(type, endian, a, v) __raw_write##type(cpu_to_##endian(v), a)
	#define in_arch(type, endian, a) endian##_to_cpu(__raw_read##type(a))

	#define out_le32(a, v) out_arch(l, le32, a, v)
	#define out_le16(a, v) out_arch(w, le16, a, v)

	#define in_le32(a) in_arch(l, le32, a)
	#define in_le16(a) in_arch(w, le16, a)

	#define out_be32(a, v) out_arch(l, be32, a, v)
	#define out_be16(a, v) out_arch(w, be16, a, v)

	#define in_be32(a) in_arch(l, be32, a)
	#define in_be16(a) in_arch(w, be16, a)

	#define out_8(a, v) __raw_writeb(v, a)
	#define in_8(a) __raw_readb(a)

	/*
	* Clear and set bits in one shot. These macros can be used to clear and
	* set multiple bits in a register using a single call. These macros can
	* also be used to set a multiple-bit bit pattern using a mask, by
	* specifying the mask in the 'clear' parameter and the new bit pattern
	* in the 'set' parameter.
	*/

	#define clrbits(type, addr, clear) \
	out_##type((addr), in_##type(addr) & ~(clear))

	#define setbits(type, addr, set) \
	out_##type((addr), in_##type(addr) \| (set))

	#define clrsetbits(type, addr, clear, set) \
	out_##type((addr), (in_##type(addr) & ~(clear)) \| (set))

	#define clrbits_be32(addr, clear) clrbits(be32, addr, clear)
	#define setbits_be32(addr, set) setbits(be32, addr, set)
	#define clrsetbits_be32(addr, clear, set) clrsetbits(be32, addr, clear, set)

	#define clrbits_le32(addr, clear) clrbits(le32, addr, clear)
	#define setbits_le32(addr, set) setbits(le32, addr, set)
	#define clrsetbits_le32(addr, clear, set) clrsetbits(le32, addr, clear, set)

	#define clrbits_be16(addr, clear) clrbits(be16, addr, clear)
	#define setbits_be16(addr, set) setbits(be16, addr, set)
	#define clrsetbits_be16(addr, clear, set) clrsetbits(be16, addr, clear, set)

	#define clrbits_le16(addr, clear) clrbits(le16, addr, clear)
	#define setbits_le16(addr, set) setbits(le16, addr, set)
	#define clrsetbits_le16(addr, clear, set) clrsetbits(le16, addr, clear, set)

	#define clrbits_8(addr, clear) clrbits(8, addr, clear)
	#define setbits_8(addr, set) setbits(8, addr, set)
	#define clrsetbits_8(addr, clear, set) clrsetbits(8, addr, clear, set)

	#include <asm-generic/io.h>

	#endif /* __ASM_ARC_IO_H */