Kernel - Added SwapEndian64 for SCSI code (coming)

[tpg/acess2.git] / KernelLand / Kernel / include / acess.h

/*
 * AcessOS Microkernel Version
 * acess.h
 */
#ifndef _ACESS_H
#define _ACESS_H
/**
 * \file acess.h
 * \brief Acess2 Kernel API Core
 */

//! NULL Pointer
#define NULL    ((void*)0)
//! Pack a structure
#define PACKED  __attribute__((packed))
//! Mark a function as not returning
#define NORETURN        __attribute__((noreturn))
//! Mark a function (or variable) as deprecated
#define DEPRECATED      __attribute__((deprecated))
//! Mark a parameter as unused
#define UNUSED(x)       UNUSED_##x __attribute__((unused))
//! Get the offset of a member in a structure
#define offsetof(st, m) ((Uint)((char *)&((st *)(0))->m - (char *)0 ))

/**
 * \name Boolean constants
 * \{
 */
#define TRUE    1
#define FALSE   0
/**
 * \}
 */

#include <arch.h>
#include <stdarg.h>
#include "errno.h"

// --- Types ---
typedef Uint32  tPID;   //!< Process ID type
typedef Uint32  tPGID;  //!< Process Group ID type
typedef Uint32  tTID;   //!< Thread ID Type
typedef Uint32  tUID;   //!< User ID Type
typedef Uint32  tGID;   //!< Group ID Type
typedef Sint64  tTimestamp;     //!< Timestamp (miliseconds since 00:00 1 Jan 1970)
typedef Sint64  tTime;  //!< Same again
typedef struct sShortSpinlock   tShortSpinlock; //!< Opaque (kinda) spinlock
typedef int     bool;   //!< Boolean type
typedef Uint64  off_t;  //!< VFS Offset

// --- Helper Macros ---
/**
 * \name Helper Macros
 * \{
 */
#define CONCAT(x,y) x ## y
#define EXPAND_CONCAT(x,y) CONCAT(x,y)
#define STR(x) #x
#define EXPAND_STR(x) STR(x)

extern char     __buildnum[];
#define BUILD_NUM       ((int)(Uint)&__buildnum)
extern const char gsGitHash[];

#define VER2(major,minor)       ((((major)&0xFF)<<8)|((minor)&0xFF))
/**
 * \}
 */

//! \brief Error number
#define errno   (*Threads_GetErrno())

// === CONSTANTS ===
// --- Memory Flags --
/**
 * \name Memory Flags
 * \{
 * \todo Move to mm_virt.h
 */
#define MM_PFLAG_RO             0x01    // Writes disallowed
#define MM_PFLAG_EXEC   0x02    // Allow execution
#define MM_PFLAG_NOPAGE 0x04    // Prevent from being paged out
#define MM_PFLAG_COW    0x08    // Copy-On-Write
#define MM_PFLAG_KERNEL 0x10    // Kernel-Only (Ring0)
/**
 * \}
 */
// --- Interface Flags & Macros
/**
 * \name Flags for Proc_Clone
 * \{
 */
//! Clone the entire process
#define CLONE_VM        0x10
//! Don't copy user pages
#define CLONE_NOUSER    0x20
//! Inherit the parent's PGID
#define CLONE_PGID      0x40
/**
 * \}
 */

// === Types ===
/**
 * \brief Thread root function
 * 
 * Function pointer prototype of a thread entrypoint. When it
 * returns, Threads_Exit is called
 */
typedef void (*tThreadFunction)(void*);

// === Kernel Export Macros ===
/**
 * \name Kernel exports
 * \{
 */
//! Kernel symbol definition
typedef struct sKernelSymbol {
        const char      *Name;  //!< Symbolic name
        tVAddr  Value;  //!< Value of the symbol
} tKernelSymbol;
//! Export a pointer symbol (function/array)
#define EXPORT(_name)   tKernelSymbol _kexp_##_name __attribute__((section ("KEXPORT"),unused))={#_name, (tVAddr)_name}
//! Export a variable
#define EXPORTV(_name)  tKernelSymbol _kexp_##_name __attribute__((section ("KEXPORT"),unused))={#_name, (tVAddr)&_name}
//! Export a symbol under another name
#define EXPORTAS(_sym,_name)    tKernelSymbol _kexp_##_name __attribute__((section ("KEXPORT"),unused))={#_name, (tVAddr)_sym}
/**
 * \}
 */

// === FUNCTIONS ===
// --- IRQs ---
/**
 * \name IRQ hander registration
 * \{
 */
extern int      IRQ_AddHandler(int Num, void (*Callback)(int, void*), void *Ptr);
extern void     IRQ_RemHandler(int Handle);
/**
 * \}
 */

// --- Logging ---
/**
 * \name Logging to kernel ring buffer
 * \{
 */
extern void     Log_KernelPanic(const char *Ident, const char *Message, ...);
extern void     Log_Panic(const char *Ident, const char *Message, ...);
extern void     Log_Error(const char *Ident, const char *Message, ...);
extern void     Log_Warning(const char *Ident, const char *Message, ...);
extern void     Log_Notice(const char *Ident, const char *Message, ...);
extern void     Log_Log(const char *Ident, const char *Message, ...);
extern void     Log_Debug(const char *Ident, const char *Message, ...);
/**
 * \}
 */

// --- Debug ---
/**
 * \name Debugging and Errors
 * \{
 */
extern void     Debug_KernelPanic(void);        //!< Initiate a kernel panic
extern void     Panic(const char *Msg, ...);    //!< Print a panic message (initiates a kernel panic)
extern void     Warning(const char *Msg, ...);  //!< Print a warning message
extern void     LogF(const char *Fmt, ...);     //!< Print a log message without a trailing newline
extern void     Log(const char *Fmt, ...);      //!< Print a log message
extern void     Debug(const char *Fmt, ...);    //!< Print a debug message (doesn't go to KTerm)
extern void     LogV(const char *Fmt, va_list Args);    //!< va_list Log message
extern void     Debug_Enter(const char *FuncName, const char *ArgTypes, ...);
extern void     Debug_Log(const char *FuncName, const char *Fmt, ...);
extern void     Debug_Leave(const char *FuncName, char RetType, ...);
extern void     Debug_HexDump(const char *Header, const void *Data, Uint Length);
#define UNIMPLEMENTED() Warning("'%s' unimplemented", __func__)
#if DEBUG
# define ENTER(_types...)       Debug_Enter((char*)__func__, _types)
# define LOG(_fmt...)   Debug_Log((char*)__func__, _fmt)
# define LEAVE(_t...)   Debug_Leave((char*)__func__, _t)
# define LEAVE_RET(_t,_v...)    do{LEAVE(_t,_v);return _v;}while(0)
# define LEAVE_RET0()   do{LEAVE('-');return;}while(0)
#else
# define ENTER(...)
# define LOG(...)
# define LEAVE(...)
# define LEAVE_RET(_t,_v...)    return (_v)
# define LEAVE_RET0()   return
#endif
#if SANITY
# define ASSERT(expr) do{if(!(expr))Panic("%s:%i - %s: Assertion '"#expr"' failed",__FILE__,__LINE__,(char*)__func__);}while(0)
#else
# define ASSERT(expr)
#endif
/**
 * \}
 */

// --- IO ---
#if NO_IO_BUS
#define inb(a)  (Log_Panic("Arch", STR(ARCHDIR)" does not support in*/out* (%s:%i)", __FILE__, __LINE__),0)
#define inw(a)  inb(a)
#define ind(a)  inb(a)
#define inq(a)  inb(a)
#define outb(a,b)       inb(a)
#define outw(a,b)       inb(a)
#define outd(a,b)       inb(a)
#define outq(a,b)       inb(a)
#else
/**
 * \name I/O Memory Access
 * \{
 */
extern void     outb(Uint16 Port, Uint8 Data);
extern void     outw(Uint16 Port, Uint16 Data);
extern void     outd(Uint16 Port, Uint32 Data);
extern void     outq(Uint16 Port, Uint64 Data);
extern Uint8    inb(Uint16 Port);
extern Uint16   inw(Uint16 Port);
extern Uint32   ind(Uint16 Port);
extern Uint64   inq(Uint16 Port);
/**
 * \}
 */
#endif
// --- Memory Management ---
/**
 * \name Memory Management
 * \{
 * \todo Move to mm_virt.h
 */
/**
 * \brief Allocate a physical page at \a VAddr
 * \param VAddr Virtual Address to allocate at
 * \return Physical address allocated
 */
extern tPAddr   MM_Allocate(tVAddr VAddr) __attribute__ ((warn_unused_result));
/**
 * \brief Deallocate a page
 * \param VAddr Virtual address to unmap
 */
extern void     MM_Deallocate(tVAddr VAddr);
/**
 * \brief Map a physical page at \a PAddr to \a VAddr
 * \param VAddr Target virtual address
 * \param PAddr Physical address to map
 * \return Boolean Success
 */
extern int      MM_Map(tVAddr VAddr, tPAddr PAddr);
/**
 * \brief Get the physical address of \a Addr
 * \param Addr  Address of the page to get the physical address of
 * \return Physical page mapped at \a Addr
 */
extern tPAddr   MM_GetPhysAddr(tVAddr Addr);
/**
 * \brief Set the access flags on a page
 * \param VAddr Virtual address of the page
 * \param Flags New flags value
 * \param Mask  Flags to set
 */
extern void     MM_SetFlags(tVAddr VAddr, Uint Flags, Uint Mask);
/**
 * \brief Get the flags on a flag
 * \param VAddr Virtual address of page
 * \return Flags value of the page
 */
extern Uint     MM_GetFlags(tVAddr VAddr);
/**
 * \brief Checks is a memory range is user accessable
 * \param VAddr Base address to check
 * \return 1 if the memory is all user-accessable, 0 otherwise
 */
#define MM_IsUser(VAddr)        (!(MM_GetFlags((VAddr))&MM_PFLAG_KERNEL))
/**
 * \brief Temporarily map a page into the address space
 * \param PAddr Physical addres to map
 * \return Virtual address of page in memory
 * \note There is only a limited ammount of slots avaliable
 */
extern tVAddr   MM_MapTemp(tPAddr PAddr);
/**
 * \brief Free a temporarily mapped page
 * \param VAddr Allocate virtual addres of page
 */
extern void     MM_FreeTemp(tVAddr VAddr);
/**
 * \brief Map a physcal address range into the virtual address space
 * \param PAddr Physical address to map in
 * \param Number        Number of pages to map
 */
extern tVAddr   MM_MapHWPages(tPAddr PAddr, Uint Number);
/**
 * \brief Allocates DMA physical memory
 * \param Pages Number of pages required
 * \param MaxBits       Maximum number of bits the physical address can have
 * \param PhysAddr      Pointer to the location to place the physical address allocated
 * \return Virtual address allocate
 */
extern tVAddr   MM_AllocDMA(int Pages, int MaxBits, tPAddr *PhysAddr);
/**
 * \brief Unmaps an allocated hardware range
 * \param VAddr Virtual address allocate by ::MM_MapHWPages or ::MM_AllocDMA
 * \param Number        Number of pages to free
 */
extern void     MM_UnmapHWPages(tVAddr VAddr, Uint Number);
/**
 * \brief Allocate a single physical page
 * \return Physical address allocated
 */
extern tPAddr   MM_AllocPhys(void);
/**
 * \brief Allocate a contiguous range of physical pages
 * \param Pages Number of pages to allocate
 * \param MaxBits       Maximum number of address bits allowed
 * \return First physical address allocated
 */
extern tPAddr   MM_AllocPhysRange(int Pages, int MaxBits);
/**
 * \brief Reference a physical page
 * \param PAddr Page to mark as referenced
 */
extern void     MM_RefPhys(tPAddr PAddr);
/**
 * \brief Dereference a physical page
 * \param PAddr Page to dereference
 */
extern void     MM_DerefPhys(tPAddr PAddr);
/**
 * \brief Get the number of times a page has been referenced
 * \param PAddr Address to check
 * \return Reference count for the page
 */
extern int      MM_GetRefCount(tPAddr PAddr);
/**
 * \brief Set the node associated with a page
 * \param PAddr Physical address of page
 * \param Node  Node pointer (tVFS_Node)
 * \return Boolean failure
 * \retval 0    Success
 * \retval 1    Page not allocated
 */
extern int      MM_SetPageNode(tPAddr PAddr, void *Node);
/**
 * \brief Get the node associated with a page
 * \param PAddr Physical address of page
 * \param Node  Node pointer (tVFS_Node) destination
 * \return Boolean failure
 * \retval 0    Success
 * \retval 1    Page not allocated
 */
extern int      MM_GetPageNode(tPAddr PAddr, void **Node);
/**
 * \}
 */

// --- Memory Manipulation ---
/**
 * \name Memory Manipulation
 * \{
 */
extern int      memcmp(const void *m1, const void *m2, size_t count);
extern void     *memcpy(void *dest, const void *src, size_t count);
extern void     *memcpyd(void *dest, const void *src, size_t count);
extern void     *memmove(void *dest, const void *src, size_t len);
extern void     *memset(void *dest, int val, size_t count);
extern void     *memsetd(void *dest, Uint32 val, size_t count);
/**
 * \}
 */
/**
 * \name Memory Validation
 * \{
 */
extern int      CheckString(const char *String);
extern int      CheckMem(const void *Mem, int Num);
/**
 * \}
 */

// --- Endianness ---
/**
 * \name Endianness Swapping
 * \{
 */
#ifdef __BIG_ENDIAN__
#define LittleEndian16(_val)    SwapEndian16(_val)
#define LittleEndian32(_val)    SwapEndian32(_val)
#define LittleEndian64(_val)    SwapEndian32(_val)
#define BigEndian16(_val)       (_val)
#define BigEndian32(_val)       (_val)
#define BigEndian64(_val)       (_val)
#else
#define LittleEndian16(_val)    (_val)
#define LittleEndian32(_val)    (_val)
#define LittleEndian64(_val)    (_val)
#define BigEndian16(_val)       SwapEndian16(_val)
#define BigEndian32(_val)       SwapEndian32(_val)
#define BigEndian64(_val)       SwapEndian64(_val)
#endif
extern Uint16   SwapEndian16(Uint16 Val);
extern Uint32   SwapEndian32(Uint32 Val);
extern Uint64   SwapEndian64(Uint64 Val);
/**
 * \}
 */

// --- Strings ---
/**
 * \name Strings
 * \{
 */
extern int      vsnprintf(char *__s, size_t __maxlen, const char *__format, va_list args);
extern int      snprintf(char *__s, size_t __n, const char *__format, ...);
extern int      sprintf(char *__s, const char *__format, ...);
extern size_t   strlen(const char *Str);
extern char     *strcpy(char *__dest, const char *__src);
extern char     *strncpy(char *__dest, const char *__src, size_t max);
extern char     *strcat(char *__dest, const char *__src);
extern char     *strncat(char *__dest, const char *__src, size_t n);
extern int      strcmp(const char *__str1, const char *__str2);
extern int      strncmp(const char *Str1, const char *Str2, size_t num);
extern int      strucmp(const char *Str1, const char *Str2);
// strdup macro is defined in heap.h
extern char     *_strdup(const char *File, int Line, const char *Str);
extern char     **str_split(const char *__str, char __ch);
extern char     *strchr(const char *__s, int __c);
extern int      strpos(const char *Str, char Ch);
extern int      strpos8(const char *str, Uint32 search);
extern void     itoa(char *buf, Uint64 num, int base, int minLength, char pad);
extern int      atoi(const char *string);
extern int      ParseInt(const char *string, int *Val);
extern int      ReadUTF8(const Uint8 *str, Uint32 *Val);
extern int      WriteUTF8(Uint8 *str, Uint32 Val);
extern int      ModUtil_SetIdent(char *Dest, const char *Value);
extern int      ModUtil_LookupString(const char **Array, const char *Needle);

extern Uint8    ByteSum(const void *Ptr, int Size);
extern int      Hex(char *Dest, size_t Size, const Uint8 *SourceData);
extern int      UnHex(Uint8 *Dest, size_t DestSize, const char *SourceString);
/**
 * \}
 */

/**
 * \brief Get a random number
 * \return Random number
 * \note Current implementation is a linear congruency
 */
extern int      rand(void);
/**
 * \brief Call a function with a variable number of arguments
 * \param Function      Function address
 * \param NArgs Number of entries in \a Args
 * \param Args  Array of arguments
 * \return Integer from called Function
 */
extern int      CallWithArgArray(void *Function, int NArgs, Uint *Args);

// --- Heap ---
#include <heap.h>
/**
 * \brief Magic heap allocation function
 */
extern void     *alloca(size_t Size);

// --- Modules ---
/**
 * \name Modules
 * \{
 */
extern int      Module_LoadMem(void *Buffer, Uint Length, const char *ArgStr);
extern int      Module_LoadFile(const char *Path, const char *ArgStr);
/**
 * \}
 */

// --- Timing ---
/**
 * \name Time and Timing
 * \{
 */
/**
 * \brief Create a timestamp from a time
 */
extern tTime    timestamp(int sec, int mins, int hrs, int day, int month, int year);
/**
 * \brief Extract the date/time from a timestamp
 */
extern void     format_date(tTime TS, int *year, int *month, int *day, int *hrs, int *mins, int *sec, int *ms);
/**
 * \brief Gets the current timestamp (miliseconds since Midnight 1st January 1970)
 */
extern Sint64   now(void);
/**
 * \}
 */

// --- Threads ---
/**
 * \name Threads and Processes
 * \{
 */
extern int      Proc_SpawnWorker(void (*Fcn)(void*), void *Data);
extern int      Proc_Spawn(const char *Path);
extern int      Proc_SysSpawn(const char *Binary, const char **ArgV, const char **EnvP, int nFD, int *FDs);
extern int      Proc_Execve(const char *File, const char **ArgV, const char **EnvP, int DataSize);
extern void     Threads_Exit(int TID, int Status);
extern void     Threads_Yield(void);
extern void     Threads_Sleep(void);
extern int      Threads_WakeTID(tTID Thread);
extern tPGID    Threads_GetPGID(void);
extern tPID     Threads_GetPID(void);
extern tTID     Threads_GetTID(void);
extern tUID     Threads_GetUID(void);
extern tGID     Threads_GetGID(void);
extern int      SpawnTask(tThreadFunction Function, void *Arg);
extern int      *Threads_GetErrno(void);
extern int      Threads_SetName(const char *NewName);
/**
 * \}
 */

// --- Simple Math ---
//! Divide and round up
extern int      DivUp(int num, int dem);
//! Divide and Modulo 64-bit unsigned integer
extern Uint64   DivMod64U(Uint64 Num, Uint64 Den, Uint64 *Rem);

static inline int MIN(int a, int b) { return a < b ? a : b; }
static inline int MAX(int a, int b) { return a > b ? a : b; }

#include <binary_ext.h>
#include <vfs_ext.h>
#include <mutex.h>

#endif