zircon/system/ulib/ddk/include/ddk/io-buffer.h - fuchsia - Git at Google

 // Copyright 2016 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef DDK_IO_BUFFER_H_
 #define DDK_IO_BUFFER_H_

 #include <zircon/assert.h>
 #include <zircon/compiler.h>
 #include <zircon/syscalls.h>
 #include <zircon/types.h>

 #include <limits.h>
 #include <stdbool.h>
 #include <stddef.h>
 #include <stdint.h>

 __BEGIN_CDECLS

 // Sentinel value for io_buffer_t's |phys| field for when it is not valid.
 #define IO_BUFFER_INVALID_PHYS 0

 typedef struct {
     zx_handle_t bti_handle; // borrowed by library
     zx_handle_t vmo_handle; // owned by library
     zx_handle_t pmt_handle; // owned by library
     size_t size;
     zx_off_t offset;
     void* virt;
     // Points to the physical page backing the start of the VMO, if this
     // io buffer was created with the IO_BUFFER_CONTIG flag.
     zx_paddr_t phys;

     // This is used for storing the addresses of the physical pages backing non
     // contiguous buffers and is set by io_buffer_physmap().
     // Each entry in the list represents a whole page and the first entry
     // points to the page containing 'offset'.
     zx_paddr_t* phys_list;
     uint64_t phys_count;
 } io_buffer_t;

 enum {
     IO_BUFFER_RO         = (0 << 0),    // map buffer read-only
     IO_BUFFER_RW         = (1 << 0),    // map buffer read/write
     IO_BUFFER_CONTIG     = (1 << 1),    // allocate physically contiguous buffer
     IO_BUFFER_UNCACHED   = (1 << 2),    // map buffer with ZX_CACHE_POLICY_UNCACHED
     IO_BUFFER_FLAGS_MASK = IO_BUFFER_RW | IO_BUFFER_CONTIG | IO_BUFFER_UNCACHED,
 };

 // Initializes a new io_buffer.  If this call fails, it is still safe to call
 // io_buffer_release on |buffer|.  |bti| is borrowed by the io_buffer and may be
 // used throughout the lifetime of the io_buffer.
 zx_status_t io_buffer_init(io_buffer_t* buffer, zx_handle_t bti, size_t size, uint32_t flags);
 // An alignment of zero is interpreted as requesting page alignment.
 // Requesting a specific alignment is not supported for non-contiguous buffers,
 // pass zero for |alignment_log2| if not passing IO_BUFFER_CONTIG.  |bti| is borrowed
 // by the io_buffer and may be used throughout the lifetime of the io_buffer.
 zx_status_t io_buffer_init_aligned(io_buffer_t* buffer, zx_handle_t bti, size_t size,
                                    uint32_t alignment_log2, uint32_t flags);

 // Initializes an io_buffer base on an existing VMO.
 // duplicates the provided vmo_handle - does not take ownership
 // |bti| is borrowed by the io_buffer and may be used throughout the lifetime of the io_buffer.
 zx_status_t io_buffer_init_vmo(io_buffer_t* buffer, zx_handle_t bti, zx_handle_t vmo_handle,
                                zx_off_t offset, uint32_t flags);

 zx_status_t io_buffer_cache_op(io_buffer_t* buffer, const uint32_t op,
                                const zx_off_t offset, const size_t size);

 // io_buffer_cache_flush() performs a cache flush on a range of memory in the buffer
 zx_status_t io_buffer_cache_flush(io_buffer_t* buffer, zx_off_t offset, size_t length);

 // io_buffer_cache_flush_invalidate() performs a cache flush and invalidate on a range of memory
 // in the buffer
 zx_status_t io_buffer_cache_flush_invalidate(io_buffer_t* buffer, zx_off_t offset, size_t length);

 // Looks up the physical pages backing this buffer's vm object.
 // This is used for non contiguous buffers.
 // The 'phys_list' and 'phys_count' fields are set if this function succeeds.
 zx_status_t io_buffer_physmap(io_buffer_t* buffer);

 // Pins and returns the physical addresses corresponding to the requested subrange
 // of the buffer.  Invoking zx_pmt_unpin() on pmt releases the pin and makes the
 // addresses invalid to use.
 zx_status_t io_buffer_physmap_range(io_buffer_t* buffer, zx_off_t offset,
                                     size_t length, size_t phys_count,
                                     zx_paddr_t* physmap, zx_handle_t* pmt);

 // Releases an io_buffer
 void io_buffer_release(io_buffer_t* buffer);

 static inline bool io_buffer_is_valid(const io_buffer_t* buffer) {
     return (buffer->vmo_handle != ZX_HANDLE_INVALID);
 }

 static inline void* io_buffer_virt(const io_buffer_t* buffer) {
     return (void*)(((uintptr_t)buffer->virt) + buffer->offset);
 }

 static inline zx_paddr_t io_buffer_phys(const io_buffer_t* buffer) {
     ZX_DEBUG_ASSERT(buffer->phys != IO_BUFFER_INVALID_PHYS);
     return buffer->phys + buffer->offset;
 }

 // Returns the buffer size available after the given offset, relative to the
 // io_buffer vmo offset.
 static inline size_t io_buffer_size(const io_buffer_t* buffer, size_t offset) {
     size_t remaining = buffer->size - buffer->offset - offset;
     // May overflow.
     if (remaining > buffer->size) {
         remaining = 0;
     }
     return remaining;
 }

 __END_CDECLS

 #ifdef __cplusplus

 namespace ddk {

 class IoBuffer {
 public:
     IoBuffer() {}
     IoBuffer(IoBuffer&& other) {
         io_buffer_ = other.io_buffer_;
         other.io_buffer_ = {};
     }
     IoBuffer& operator=(IoBuffer&& other) {
         io_buffer_ = other.io_buffer_;
         other.io_buffer_ = {};
         return *this;
     }
     ~IoBuffer() { io_buffer_release(&io_buffer_); }

     inline void release() { io_buffer_release(&io_buffer_); }

     inline zx_status_t Init(zx_handle_t bti, size_t size, uint32_t flags) {
         return io_buffer_init(&io_buffer_, bti, size, flags);
     }
     inline zx_status_t InitAligned(zx_handle_t bti, size_t size, uint32_t alignment_log2,
                                    uint32_t flags) {
         return io_buffer_init_aligned(&io_buffer_, bti, size, alignment_log2, flags);
     }
     inline zx_status_t InitVmo(zx_handle_t bti, zx_handle_t vmo_handle, zx_off_t offset,
                                uint32_t flags) {
         return io_buffer_init_vmo(&io_buffer_, bti, vmo_handle, offset, flags);
     }

     inline zx_status_t CacheOp(uint32_t op, zx_off_t offset, size_t size) {
         return io_buffer_cache_op(&io_buffer_, op, offset, size);
     }
     inline zx_status_t CacheFlush(zx_off_t offset, size_t length) {
         return  io_buffer_cache_flush(&io_buffer_, offset, length);
     }
     inline zx_status_t CacheFlushInvalidate(zx_off_t offset, size_t length) {
         return  io_buffer_cache_flush_invalidate(&io_buffer_, offset, length);
     }

     inline zx_status_t PhysMap() {
         return io_buffer_physmap(&io_buffer_);
     }
     inline zx_status_t PhysMapRange(zx_off_t offset, size_t length, size_t phys_count,
                                     zx_paddr_t* physmap, zx_handle_t* pmt) {
         return io_buffer_physmap_range(&io_buffer_, offset, length, phys_count, physmap, pmt);
     }

     inline bool is_valid() const {
         return io_buffer_is_valid(&io_buffer_);
     }
     inline void* virt() const {
         return io_buffer_virt(&io_buffer_);
     }
     inline zx_paddr_t phys() const {
         return io_buffer_phys(&io_buffer_);
     }

     inline const zx_paddr_t* phys_list() const {
         return io_buffer_.phys_list;
     }
     inline uint64_t phys_count() const {
         return io_buffer_.phys_count;
     }
     inline size_t size() const {
         return io_buffer_.size;
     }

 private:
     io_buffer_t io_buffer_ = {};
 };

 } // namespace ddk

 #endif // __cplusplus

 #endif  // DDK_IO_BUFFER_H_
	// Copyright 2016 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef DDK_IO_BUFFER_H_
	#define DDK_IO_BUFFER_H_

	#include <zircon/assert.h>
	#include <zircon/compiler.h>
	#include <zircon/syscalls.h>
	#include <zircon/types.h>

	#include <limits.h>
	#include <stdbool.h>
	#include <stddef.h>
	#include <stdint.h>

	__BEGIN_CDECLS

	// Sentinel value for io_buffer_t's \|phys\| field for when it is not valid.
	#define IO_BUFFER_INVALID_PHYS 0

	typedef struct {
	zx_handle_t bti_handle; // borrowed by library
	zx_handle_t vmo_handle; // owned by library
	zx_handle_t pmt_handle; // owned by library
	size_t size;
	zx_off_t offset;
	void* virt;
	// Points to the physical page backing the start of the VMO, if this
	// io buffer was created with the IO_BUFFER_CONTIG flag.
	zx_paddr_t phys;

	// This is used for storing the addresses of the physical pages backing non
	// contiguous buffers and is set by io_buffer_physmap().
	// Each entry in the list represents a whole page and the first entry
	// points to the page containing 'offset'.
	zx_paddr_t* phys_list;
	uint64_t phys_count;
	} io_buffer_t;

	enum {
	IO_BUFFER_RO = (0 << 0), // map buffer read-only
	IO_BUFFER_RW = (1 << 0), // map buffer read/write
	IO_BUFFER_CONTIG = (1 << 1), // allocate physically contiguous buffer
	IO_BUFFER_UNCACHED = (1 << 2), // map buffer with ZX_CACHE_POLICY_UNCACHED
	IO_BUFFER_FLAGS_MASK = IO_BUFFER_RW \| IO_BUFFER_CONTIG \| IO_BUFFER_UNCACHED,
	};

	// Initializes a new io_buffer. If this call fails, it is still safe to call
	// io_buffer_release on \|buffer\|. \|bti\| is borrowed by the io_buffer and may be
	// used throughout the lifetime of the io_buffer.
	zx_status_t io_buffer_init(io_buffer_t* buffer, zx_handle_t bti, size_t size, uint32_t flags);
	// An alignment of zero is interpreted as requesting page alignment.
	// Requesting a specific alignment is not supported for non-contiguous buffers,
	// pass zero for \|alignment_log2\| if not passing IO_BUFFER_CONTIG. \|bti\| is borrowed
	// by the io_buffer and may be used throughout the lifetime of the io_buffer.
	zx_status_t io_buffer_init_aligned(io_buffer_t* buffer, zx_handle_t bti, size_t size,
	uint32_t alignment_log2, uint32_t flags);

	// Initializes an io_buffer base on an existing VMO.
	// duplicates the provided vmo_handle - does not take ownership
	// \|bti\| is borrowed by the io_buffer and may be used throughout the lifetime of the io_buffer.
	zx_status_t io_buffer_init_vmo(io_buffer_t* buffer, zx_handle_t bti, zx_handle_t vmo_handle,
	zx_off_t offset, uint32_t flags);

	zx_status_t io_buffer_cache_op(io_buffer_t* buffer, const uint32_t op,
	const zx_off_t offset, const size_t size);

	// io_buffer_cache_flush() performs a cache flush on a range of memory in the buffer
	zx_status_t io_buffer_cache_flush(io_buffer_t* buffer, zx_off_t offset, size_t length);

	// io_buffer_cache_flush_invalidate() performs a cache flush and invalidate on a range of memory
	// in the buffer
	zx_status_t io_buffer_cache_flush_invalidate(io_buffer_t* buffer, zx_off_t offset, size_t length);

	// Looks up the physical pages backing this buffer's vm object.
	// This is used for non contiguous buffers.
	// The 'phys_list' and 'phys_count' fields are set if this function succeeds.
	zx_status_t io_buffer_physmap(io_buffer_t* buffer);

	// Pins and returns the physical addresses corresponding to the requested subrange
	// of the buffer. Invoking zx_pmt_unpin() on pmt releases the pin and makes the
	// addresses invalid to use.
	zx_status_t io_buffer_physmap_range(io_buffer_t* buffer, zx_off_t offset,
	size_t length, size_t phys_count,
	zx_paddr_t* physmap, zx_handle_t* pmt);

	// Releases an io_buffer
	void io_buffer_release(io_buffer_t* buffer);

	static inline bool io_buffer_is_valid(const io_buffer_t* buffer) {
	return (buffer->vmo_handle != ZX_HANDLE_INVALID);
	}

	static inline void* io_buffer_virt(const io_buffer_t* buffer) {
	return (void*)(((uintptr_t)buffer->virt) + buffer->offset);
	}

	static inline zx_paddr_t io_buffer_phys(const io_buffer_t* buffer) {
	ZX_DEBUG_ASSERT(buffer->phys != IO_BUFFER_INVALID_PHYS);
	return buffer->phys + buffer->offset;
	}

	// Returns the buffer size available after the given offset, relative to the
	// io_buffer vmo offset.
	static inline size_t io_buffer_size(const io_buffer_t* buffer, size_t offset) {
	size_t remaining = buffer->size - buffer->offset - offset;
	// May overflow.
	if (remaining > buffer->size) {
	remaining = 0;
	}
	return remaining;
	}

	__END_CDECLS

	#ifdef __cplusplus

	namespace ddk {

	class IoBuffer {
	public:
	IoBuffer() {}
	IoBuffer(IoBuffer&& other) {
	io_buffer_ = other.io_buffer_;
	other.io_buffer_ = {};
	}
	IoBuffer& operator=(IoBuffer&& other) {
	io_buffer_ = other.io_buffer_;
	other.io_buffer_ = {};
	return *this;
	}
	~IoBuffer() { io_buffer_release(&io_buffer_); }

	inline void release() { io_buffer_release(&io_buffer_); }

	inline zx_status_t Init(zx_handle_t bti, size_t size, uint32_t flags) {
	return io_buffer_init(&io_buffer_, bti, size, flags);
	}
	inline zx_status_t InitAligned(zx_handle_t bti, size_t size, uint32_t alignment_log2,
	uint32_t flags) {
	return io_buffer_init_aligned(&io_buffer_, bti, size, alignment_log2, flags);
	}
	inline zx_status_t InitVmo(zx_handle_t bti, zx_handle_t vmo_handle, zx_off_t offset,
	uint32_t flags) {
	return io_buffer_init_vmo(&io_buffer_, bti, vmo_handle, offset, flags);
	}

	inline zx_status_t CacheOp(uint32_t op, zx_off_t offset, size_t size) {
	return io_buffer_cache_op(&io_buffer_, op, offset, size);
	}
	inline zx_status_t CacheFlush(zx_off_t offset, size_t length) {
	return io_buffer_cache_flush(&io_buffer_, offset, length);
	}
	inline zx_status_t CacheFlushInvalidate(zx_off_t offset, size_t length) {
	return io_buffer_cache_flush_invalidate(&io_buffer_, offset, length);
	}

	inline zx_status_t PhysMap() {
	return io_buffer_physmap(&io_buffer_);
	}
	inline zx_status_t PhysMapRange(zx_off_t offset, size_t length, size_t phys_count,
	zx_paddr_t* physmap, zx_handle_t* pmt) {
	return io_buffer_physmap_range(&io_buffer_, offset, length, phys_count, physmap, pmt);
	}

	inline bool is_valid() const {
	return io_buffer_is_valid(&io_buffer_);
	}
	inline void* virt() const {
	return io_buffer_virt(&io_buffer_);
	}
	inline zx_paddr_t phys() const {
	return io_buffer_phys(&io_buffer_);
	}

	inline const zx_paddr_t* phys_list() const {
	return io_buffer_.phys_list;
	}
	inline uint64_t phys_count() const {
	return io_buffer_.phys_count;
	}
	inline size_t size() const {
	return io_buffer_.size;
	}

	private:
	io_buffer_t io_buffer_ = {};
	};

	} // namespace ddk

	#endif // __cplusplus

	#endif // DDK_IO_BUFFER_H_