kolibrios/kernel/trunk/blkdev/bd_drv.inc

;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;                                                              ;;
;; Copyright (C) KolibriOS team 2004-2013. All rights reserved. ;;
;; Distributed under terms of the GNU General Public License    ;;
;;                                                              ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

$Revision$


; Access through BIOS by diamond
iglobal
align 4
bd_callbacks:
        dd      bd_callbacks.end - bd_callbacks         ; strucsize
        dd      0       ; no close function
        dd      0       ; no closemedia function
        dd      bd_querymedia
        dd      bd_read_interface
        dd      bd_write_interface
        dd      0       ; no flush function
        dd      0       ; use default cache size
.end:
endg

proc bd_read_interface stdcall uses edi, \
        userdata, buffer, startsector:qword, numsectors
        ; userdata = old [hdpos] = 80h + index in NumBiosDisks
        ; buffer = pointer to buffer for data
        ; startsector = 64-bit start sector
        ; numsectors = pointer to number of sectors on input,
        ;  must be filled with number of sectors really read
locals
sectors_todo    dd      ?
endl
; 1. Initialize number of sectors: get number of requested sectors
; and say that no sectors were read yet.
        mov     ecx, [numsectors]
        mov     eax, [ecx]
        mov     dword [ecx], 0
        mov     [sectors_todo], eax
; 2. Acquire the global lock.
        mov     ecx, ide_mutex
        call    mutex_lock
; 3. Convert parameters to the form suitable for worker procedures.
; Underlying procedures do not know about 64-bit sectors.
; Worker procedures use global variables and edi for [buffer].
        cmp     dword [startsector+4], 0
        jnz     .fail
        and     [hd_error], 0
        mov     eax, [userdata]
        mov     [hdpos], eax
        mov     eax, dword [startsector]
        mov     edi, [buffer]
; 4. Worker procedures take one sectors per time, so loop over all sectors to read.
.sectors_loop:
        call    bd_read
        cmp     [hd_error], 0
        jnz     .fail
        mov     ecx, [numsectors]
        inc     dword [ecx]     ; one more sector is read
        dec     [sectors_todo]
        jz      .done
        inc     eax
        jnz     .sectors_loop
; 5. Loop is done, either due to error or because everything is done.
; Release the global lock and return the corresponding status.
.fail:
        mov     ecx, ide_mutex
        call    mutex_unlock
        or      eax, -1
        ret
.done:
        mov     ecx, ide_mutex
        call    mutex_unlock
        xor     eax, eax
        ret
endp

proc bd_write_interface stdcall uses esi edi, \
        userdata, buffer, startsector:qword, numsectors
        ; userdata = old [hdpos] = 80h + index in NumBiosDisks
        ; buffer = pointer to buffer with data
        ; startsector = 64-bit start sector
        ; numsectors = pointer to number of sectors on input,
        ;  must be filled with number of sectors really written
locals
sectors_todo    dd      ?
endl
; 1. Initialize number of sectors: get number of requested sectors
; and say that no sectors were read yet.      
        mov     ecx, [numsectors]
        mov     eax, [ecx]
        mov     dword [ecx], 0
        mov     [sectors_todo], eax
; 2. Acquire the global lock.
        mov     ecx, ide_mutex
        call    mutex_lock
; 3. Convert parameters to the form suitable for worker procedures.
; Underlying procedures do not know about 64-bit sectors.
; Worker procedures use global variables and esi for [buffer].
        cmp     dword [startsector+4], 0
        jnz     .fail
        and     [hd_error], 0
        mov     eax, [userdata]
        mov     [hdpos], eax
        mov     esi, [buffer]
        lea     edi, [startsector]
        mov     [cache_chain_ptr], edi
; 4. Worker procedures take max 16 sectors per time,
; loop until all sectors will be processed.
.sectors_loop:
        mov     ecx, 16
        cmp     ecx, [sectors_todo]
        jbe     @f
        mov     ecx, [sectors_todo]
@@:
        mov     [cache_chain_size], cl
        call    bd_write_cache_chain
        cmp     [hd_error], 0
        jnz     .fail
        movzx   ecx, [cache_chain_size]
        mov     eax, [numsectors]
        add     [eax], ecx
        sub     [sectors_todo], ecx
        jz      .done
        add     [edi], ecx
        jc      .fail
        shl     ecx, 9
        add     esi, ecx
        jmp     .sectors_loop
; 5. Loop is done, either due to error or because everything is done.
; Release the global lock and return the corresponding status.
.fail:
        mov     ecx, ide_mutex
        call    mutex_unlock
        or      eax, -1
        ret
.done:
        mov     ecx, ide_mutex
        call    mutex_unlock
        xor     eax, eax
        ret
endp

; This is a stub.
proc bd_querymedia stdcall, hd_data, mediainfo
        mov     eax, [mediainfo]
        mov     [eax+DISKMEDIAINFO.Flags], 0
        mov     [eax+DISKMEDIAINFO.SectorSize], 512
        or      dword [eax+DISKMEDIAINFO.Capacity], 0xFFFFFFFF
        or      dword [eax+DISKMEDIAINFO.Capacity+4], 0xFFFFFFFF
        xor     eax, eax
        ret
endp

;-----------------------------------------------------------------------------
; \begin{diamond}
uglobal
bios_hdpos      dd 0       ; 0 is invalid value for [hdpos]
bios_cur_sector dd ?
bios_read_len   dd ?
endg
;-----------------------------------------------------------------------------
align 4
bd_read:
        push    eax
        push    edx
        mov     edx, [bios_hdpos]
        cmp     edx, [hdpos]
        jne     .notread
        mov     edx, [bios_cur_sector]
        cmp     eax, edx
        jb      .notread
        add     edx, [bios_read_len]
        dec     edx
        cmp     eax, edx
        ja      .notread
        sub     eax, [bios_cur_sector]
        shl     eax, 9
        add     eax, (OS_BASE+0x9A000)
        push    ecx esi
        mov     esi, eax
        mov     ecx, 512/4
        cld
        rep movsd
        pop     esi ecx
        pop     edx
        pop     eax
        ret
.notread:
        push    ecx
        mov     dl, 42h
        mov     ecx, 16
        call    int13_call
        pop     ecx
        test    eax, eax
        jnz     .v86err
        test    edx, edx
        jz      .readerr
        mov     [bios_read_len], edx
        mov     edx, [hdpos]
        mov     [bios_hdpos], edx
        pop     edx
        pop     eax
        mov     [bios_cur_sector], eax
        jmp     bd_read
.readerr:
.v86err:
        mov     [hd_error], 1
        jmp     hd_read_error
;-----------------------------------------------------------------------------
align 4
bd_write_cache_chain:
        pusha
        mov     edi, OS_BASE + 0x9A000
        movzx   ecx, [cache_chain_size]
        push    ecx
        shl     ecx, 9-2
        rep movsd
        pop     ecx
        mov     dl, 43h
        mov     eax, [cache_chain_ptr]
        mov     eax, [eax]
        call    int13_call
        test    eax, eax
        jnz     .v86err
        cmp     edx, ecx
        jnz     .writeerr
        popa
        ret
.v86err:
.writeerr:
        popa
        mov     [hd_error], 1
        jmp     hd_write_error
;-----------------------------------------------------------------------------
uglobal
int13_regs_in   rb sizeof.v86_regs
int13_regs_out  rb sizeof.v86_regs
endg
;-----------------------------------------------------------------------------
align 4
int13_call:
; Because this code uses fixed addresses,
; it can not be run simultaniously by many threads.
; In current implementation it is protected by common mutex 'ide_status'
        mov     word [OS_BASE + 510h], 10h             ; packet length
        mov     word [OS_BASE + 512h], cx              ; number of sectors
        mov     dword [OS_BASE + 514h], 9A000000h      ; buffer 9A00:0000
        mov     dword [OS_BASE + 518h], eax
        and     dword [OS_BASE + 51Ch], 0
        push    ebx ecx esi edi
        mov     ebx, int13_regs_in
        mov     edi, ebx
        mov     ecx, sizeof.v86_regs/4
        xor     eax, eax
        rep stosd
        mov     byte [ebx+v86_regs.eax+1], dl
        mov     eax, [hdpos]
        lea     eax, [BiosDisksData+(eax-80h)*4]
        mov     dl, [eax]
        mov     byte [ebx+v86_regs.edx], dl
        movzx   edx, byte [eax+1]
;        mov     dl, 5
        test    edx, edx
        jnz     .hasirq
        dec     edx
        jmp     @f
.hasirq:
        pushad
        stdcall enable_irq, edx
        popad
@@:
        mov     word [ebx+v86_regs.esi], 510h
        mov     word [ebx+v86_regs.ss], 9000h
        mov     word [ebx+v86_regs.esp], 0A000h
        mov     word [ebx+v86_regs.eip], 500h
        mov     [ebx+v86_regs.eflags], 20200h
        mov     esi, [sys_v86_machine]
        mov     ecx, 0x502
        push    fs
        call    v86_start
        pop     fs
        and     [bios_hdpos], 0
        pop     edi esi ecx ebx
        movzx   edx, byte [OS_BASE + 512h]
        test    byte [int13_regs_out+v86_regs.eflags], 1
        jnz     @f
        mov     edx, ecx
@@:
        ret
; \end{diamond}
split /hd and /bd access into separate includes git-svn-id: svn://kolibrios.org@4420 a494cfbc-eb01-0410-851d-a64ba20cac60 2013-12-30 12:42:20 +01:00			`;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;`
			`;; ;;`
			`;; Copyright (C) KolibriOS team 2004-2013. All rights reserved. ;;`
			`;; Distributed under terms of the GNU General Public License ;;`
			`;; ;;`
			`;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;`

			$Revision$


			`; Access through BIOS by diamond`
			`iglobal`
			`align 4`
			`bd_callbacks:`
			`dd bd_callbacks.end - bd_callbacks ; strucsize`
			`dd 0 ; no close function`
			`dd 0 ; no closemedia function`
			`dd bd_querymedia`
			`dd bd_read_interface`
			`dd bd_write_interface`
			`dd 0 ; no flush function`
			`dd 0 ; use default cache size`
			`.end:`
			`endg`

			`proc bd_read_interface stdcall uses edi, \`
			`userdata, buffer, startsector:qword, numsectors`
			`; userdata = old [hdpos] = 80h + index in NumBiosDisks`
			`; buffer = pointer to buffer for data`
			`; startsector = 64-bit start sector`
			`; numsectors = pointer to number of sectors on input,`
			`; must be filled with number of sectors really read`
			`locals`
			`sectors_todo dd ?`
			`endl`
			`; 1. Initialize number of sectors: get number of requested sectors`
			`; and say that no sectors were read yet.`
			`mov ecx, [numsectors]`
			`mov eax, [ecx]`
			`mov dword [ecx], 0`
			`mov [sectors_todo], eax`
			`; 2. Acquire the global lock.`
			`mov ecx, ide_mutex`
			`call mutex_lock`
			`; 3. Convert parameters to the form suitable for worker procedures.`
			`; Underlying procedures do not know about 64-bit sectors.`
			`; Worker procedures use global variables and edi for [buffer].`
			`cmp dword [startsector+4], 0`
			`jnz .fail`
			`and [hd_error], 0`
			`mov eax, [userdata]`
			`mov [hdpos], eax`
			`mov eax, dword [startsector]`
			`mov edi, [buffer]`
			`; 4. Worker procedures take one sectors per time, so loop over all sectors to read.`
			`.sectors_loop:`
			`call bd_read`
			`cmp [hd_error], 0`
			`jnz .fail`
			`mov ecx, [numsectors]`
			`inc dword [ecx] ; one more sector is read`
			`dec [sectors_todo]`
			`jz .done`
			`inc eax`
			`jnz .sectors_loop`
			`; 5. Loop is done, either due to error or because everything is done.`
			`; Release the global lock and return the corresponding status.`
			`.fail:`
			`mov ecx, ide_mutex`
			`call mutex_unlock`
			`or eax, -1`
			`ret`
			`.done:`
			`mov ecx, ide_mutex`
			`call mutex_unlock`
			`xor eax, eax`
			`ret`
			`endp`

			`proc bd_write_interface stdcall uses esi edi, \`
			`userdata, buffer, startsector:qword, numsectors`
			`; userdata = old [hdpos] = 80h + index in NumBiosDisks`
			`; buffer = pointer to buffer with data`
			`; startsector = 64-bit start sector`
			`; numsectors = pointer to number of sectors on input,`
			`; must be filled with number of sectors really written`
			`locals`
			`sectors_todo dd ?`
			`endl`
			`; 1. Initialize number of sectors: get number of requested sectors`
			`; and say that no sectors were read yet.`
			`mov ecx, [numsectors]`
			`mov eax, [ecx]`
			`mov dword [ecx], 0`
			`mov [sectors_todo], eax`
			`; 2. Acquire the global lock.`
			`mov ecx, ide_mutex`
			`call mutex_lock`
			`; 3. Convert parameters to the form suitable for worker procedures.`
			`; Underlying procedures do not know about 64-bit sectors.`
			`; Worker procedures use global variables and esi for [buffer].`
			`cmp dword [startsector+4], 0`
			`jnz .fail`
			`and [hd_error], 0`
			`mov eax, [userdata]`
			`mov [hdpos], eax`
			`mov esi, [buffer]`
			`lea edi, [startsector]`
			`mov [cache_chain_ptr], edi`
			`; 4. Worker procedures take max 16 sectors per time,`
			`; loop until all sectors will be processed.`
			`.sectors_loop:`
			`mov ecx, 16`
			`cmp ecx, [sectors_todo]`
			`jbe @f`
			`mov ecx, [sectors_todo]`
			`@@:`
			`mov [cache_chain_size], cl`
			`call bd_write_cache_chain`
			`cmp [hd_error], 0`
			`jnz .fail`
			`movzx ecx, [cache_chain_size]`
			`mov eax, [numsectors]`
			`add [eax], ecx`
			`sub [sectors_todo], ecx`
			`jz .done`
			`add [edi], ecx`
			`jc .fail`
			`shl ecx, 9`
			`add esi, ecx`
			`jmp .sectors_loop`
			`; 5. Loop is done, either due to error or because everything is done.`
			`; Release the global lock and return the corresponding status.`
			`.fail:`
			`mov ecx, ide_mutex`
			`call mutex_unlock`
			`or eax, -1`
			`ret`
			`.done:`
			`mov ecx, ide_mutex`
			`call mutex_unlock`
			`xor eax, eax`
			`ret`
			`endp`

			`; This is a stub.`
			`proc bd_querymedia stdcall, hd_data, mediainfo`
			`mov eax, [mediainfo]`
			`mov [eax+DISKMEDIAINFO.Flags], 0`
			`mov [eax+DISKMEDIAINFO.SectorSize], 512`
			`or dword [eax+DISKMEDIAINFO.Capacity], 0xFFFFFFFF`
			`or dword [eax+DISKMEDIAINFO.Capacity+4], 0xFFFFFFFF`
			`xor eax, eax`
			`ret`
			`endp`

			`;-----------------------------------------------------------------------------`
			`; \begin{diamond}`
			`uglobal`
			`bios_hdpos dd 0 ; 0 is invalid value for [hdpos]`
			`bios_cur_sector dd ?`
			`bios_read_len dd ?`
			`endg`
			`;-----------------------------------------------------------------------------`
			`align 4`
			`bd_read:`
			`push eax`
			`push edx`
			`mov edx, [bios_hdpos]`
			`cmp edx, [hdpos]`
			`jne .notread`
			`mov edx, [bios_cur_sector]`
			`cmp eax, edx`
			`jb .notread`
			`add edx, [bios_read_len]`
			`dec edx`
			`cmp eax, edx`
			`ja .notread`
			`sub eax, [bios_cur_sector]`
			`shl eax, 9`
			`add eax, (OS_BASE+0x9A000)`
			`push ecx esi`
			`mov esi, eax`
			`mov ecx, 512/4`
			`cld`
			`rep movsd`
			`pop esi ecx`
			`pop edx`
			`pop eax`
			`ret`
			`.notread:`
			`push ecx`
			`mov dl, 42h`
			`mov ecx, 16`
			`call int13_call`
			`pop ecx`
			`test eax, eax`
			`jnz .v86err`
			`test edx, edx`
			`jz .readerr`
			`mov [bios_read_len], edx`
			`mov edx, [hdpos]`
			`mov [bios_hdpos], edx`
			`pop edx`
			`pop eax`
			`mov [bios_cur_sector], eax`
			`jmp bd_read`
			`.readerr:`
			`.v86err:`
			`mov [hd_error], 1`
			`jmp hd_read_error`
			`;-----------------------------------------------------------------------------`
			`align 4`
			`bd_write_cache_chain:`
			`pusha`
			`mov edi, OS_BASE + 0x9A000`
			`movzx ecx, [cache_chain_size]`
			`push ecx`
			`shl ecx, 9-2`
			`rep movsd`
			`pop ecx`
			`mov dl, 43h`
			`mov eax, [cache_chain_ptr]`
			`mov eax, [eax]`
			`call int13_call`
			`test eax, eax`
			`jnz .v86err`
			`cmp edx, ecx`
			`jnz .writeerr`
			`popa`
			`ret`
			`.v86err:`
			`.writeerr:`
			`popa`
			`mov [hd_error], 1`
			`jmp hd_write_error`
			`;-----------------------------------------------------------------------------`
			`uglobal`
			`int13_regs_in rb sizeof.v86_regs`
			`int13_regs_out rb sizeof.v86_regs`
			`endg`
			`;-----------------------------------------------------------------------------`
			`align 4`
			`int13_call:`
			`; Because this code uses fixed addresses,`
			`; it can not be run simultaniously by many threads.`
			`; In current implementation it is protected by common mutex 'ide_status'`
			`mov word [OS_BASE + 510h], 10h ; packet length`
			`mov word [OS_BASE + 512h], cx ; number of sectors`
			`mov dword [OS_BASE + 514h], 9A000000h ; buffer 9A00:0000`
			`mov dword [OS_BASE + 518h], eax`
			`and dword [OS_BASE + 51Ch], 0`
			`push ebx ecx esi edi`
			`mov ebx, int13_regs_in`
			`mov edi, ebx`
			`mov ecx, sizeof.v86_regs/4`
			`xor eax, eax`
			`rep stosd`
			`mov byte [ebx+v86_regs.eax+1], dl`
			`mov eax, [hdpos]`
			`lea eax, [BiosDisksData+(eax-80h)*4]`
			`mov dl, [eax]`
			`mov byte [ebx+v86_regs.edx], dl`
			`movzx edx, byte [eax+1]`
			`; mov dl, 5`
			`test edx, edx`
			`jnz .hasirq`
			`dec edx`
			`jmp @f`
			`.hasirq:`
			`pushad`
			`stdcall enable_irq, edx`
			`popad`
			`@@:`
			`mov word [ebx+v86_regs.esi], 510h`
			`mov word [ebx+v86_regs.ss], 9000h`
			`mov word [ebx+v86_regs.esp], 0A000h`
			`mov word [ebx+v86_regs.eip], 500h`
			`mov [ebx+v86_regs.eflags], 20200h`
			`mov esi, [sys_v86_machine]`
			`mov ecx, 0x502`
			`push fs`
			`call v86_start`
			`pop fs`
			`and [bios_hdpos], 0`
			`pop edi esi ecx ebx`
			`movzx edx, byte [OS_BASE + 512h]`
			`test byte [int13_regs_out+v86_regs.eflags], 1`
			`jnz @f`
			`mov edx, ecx`
			`@@:`
			`ret`
			`; \end{diamond}`