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/*
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* QEMU PowerMac CUDA device support
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*
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* Copyright ( c ) 2004 - 2007 Fabrice Bellard
* Copyright ( c ) 2007 Jocelyn Mayer
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*
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* Permission is hereby granted , free of charge , to any person obtaining a copy
* of this software and associated documentation files ( the "Software" ), to deal
* in the Software without restriction , including without limitation the rights
* to use , copy , modify , merge , publish , distribute , sublicense , and / or sell
* copies of the Software , and to permit persons to whom the Software is
* furnished to do so , subject to the following conditions :
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software .
*
* THE SOFTWARE IS PROVIDED "AS IS" , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
* IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
* LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM ,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE .
*/
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# include "hw.h"
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# include "ppc_mac.h"
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# include "qemu-timer.h" # include "sysemu.h"
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/* XXX: implement all timer modes */
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/* debug CUDA */
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// # define DEBUG_CUDA
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/* debug CUDA packets */
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// # define DEBUG_CUDA_PACKET
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# ifdef DEBUG_CUDA
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# define CUDA_DPRINTF ( fmt , ...) \ do { printf ( "CUDA: " fmt , ## __VA_ARGS__ ); } while ( 0 )
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# else
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# define CUDA_DPRINTF ( fmt , ...)
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# endif
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/* Bits in B data register: all active low */ # define TREQ 0x08 /* Transfer request (input) */ # define TACK 0x10 /* Transfer acknowledge (output) */ # define TIP 0x20 /* Transfer in progress (output) */ /* Bits in ACR */ # define SR_CTRL 0x1c /* Shift register control bits */ # define SR_EXT 0x0c /* Shift on external clock */ # define SR_OUT 0x10 /* Shift out if 1 */ /* Bits in IFR and IER */ # define IER_SET 0x80 /* set bits in IER */ # define IER_CLR 0 /* clear bits in IER */ # define SR_INT 0x04 /* Shift register full/empty */ # define T1_INT 0x40 /* Timer 1 interrupt */
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# define T2_INT 0x20 /* Timer 2 interrupt */
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/* Bits in ACR */ # define T1MODE 0xc0 /* Timer 1 mode */ # define T1MODE_CONT 0x40 /* continuous interrupts */ /* commands (1st byte) */ # define ADB_PACKET 0 # define CUDA_PACKET 1 # define ERROR_PACKET 2 # define TIMER_PACKET 3 # define POWER_PACKET 4 # define MACIIC_PACKET 5 # define PMU_PACKET 6 /* CUDA commands (2nd byte) */ # define CUDA_WARM_START 0x0 # define CUDA_AUTOPOLL 0x1 # define CUDA_GET_6805_ADDR 0x2 # define CUDA_GET_TIME 0x3 # define CUDA_GET_PRAM 0x7 # define CUDA_SET_6805_ADDR 0x8 # define CUDA_SET_TIME 0x9 # define CUDA_POWERDOWN 0xa # define CUDA_POWERUP_TIME 0xb # define CUDA_SET_PRAM 0xc # define CUDA_MS_RESET 0xd # define CUDA_SEND_DFAC 0xe # define CUDA_BATTERY_SWAP_SENSE 0x10 # define CUDA_RESET_SYSTEM 0x11 # define CUDA_SET_IPL 0x12 # define CUDA_FILE_SERVER_FLAG 0x13 # define CUDA_SET_AUTO_RATE 0x14 # define CUDA_GET_AUTO_RATE 0x16 # define CUDA_SET_DEVICE_LIST 0x19 # define CUDA_GET_DEVICE_LIST 0x1a # define CUDA_SET_ONE_SECOND_MODE 0x1b # define CUDA_SET_POWER_MESSAGES 0x21 # define CUDA_GET_SET_IIC 0x22 # define CUDA_WAKEUP 0x23 # define CUDA_TIMER_TICKLE 0x24 # define CUDA_COMBINED_FORMAT_IIC 0x25 # define CUDA_TIMER_FREQ ( 4700000 / 6 )
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# define CUDA_ADB_POLL_FREQ 50
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/* CUDA returns time_t's offset from Jan 1, 1904, not 1970 */ # define RTC_OFFSET 2082844800
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typedef struct CUDATimer {
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int index ;
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uint16_t latch ;
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uint16_t counter_value ; /* counter value at load time */
int64_t load_time ;
int64_t next_irq_time ;
QEMUTimer * timer ;
} CUDATimer ; typedef struct CUDAState { /* cuda registers */
uint8_t b ; /* B-side data */
uint8_t a ; /* A-side data */
uint8_t dirb ; /* B-side direction (1=output) */
uint8_t dira ; /* A-side direction (1=output) */
uint8_t sr ; /* Shift register */
uint8_t acr ; /* Auxiliary control register */
uint8_t pcr ; /* Peripheral control register */
uint8_t ifr ; /* Interrupt flag register */
uint8_t ier ; /* Interrupt enable register */
uint8_t anh ; /* A-side data, no handshake */
CUDATimer timers [ 2 ];
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uint32_t tick_offset ;
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uint8_t last_b ; /* last value of B register */
uint8_t last_acr ; /* last value of B register */
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int data_in_size ;
int data_in_index ;
int data_out_index ;
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qemu_irq irq ;
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uint8_t autopoll ;
uint8_t data_in [ 128 ];
uint8_t data_out [ 16 ];
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QEMUTimer * adb_poll_timer ;
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} CUDAState ; static CUDAState cuda_state ; ADBBusState adb_bus ; static void cuda_update ( CUDAState * s );
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static void cuda_receive_packet_from_host ( CUDAState * s ,
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const uint8_t * data , int len );
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static void cuda_timer_update ( CUDAState * s , CUDATimer * ti ,
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int64_t current_time );
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static void cuda_update_irq ( CUDAState * s ) {
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if ( s -> ifr & s -> ier & ( SR_INT | T1_INT )) {
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qemu_irq_raise ( s -> irq );
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} else {
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qemu_irq_lower ( s -> irq );
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}
} static unsigned int get_counter ( CUDATimer * s ) { int64_t d ;
unsigned int counter ;
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d = muldiv64 ( qemu_get_clock ( vm_clock ) - s -> load_time ,
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CUDA_TIMER_FREQ , ticks_per_sec );
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if ( s -> index == 0 ) {
/* the timer goes down from latch to -1 (period of latch + 2) */
if ( d <= ( s -> counter_value + 1 )) {
counter = ( s -> counter_value - d ) & 0xffff ;
} else {
counter = ( d - ( s -> counter_value + 1 )) % ( s -> latch + 2 );
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counter = ( s -> latch - counter ) & 0xffff ;
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}
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} else {
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counter = ( s -> counter_value - d ) & 0xffff ;
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}
return counter ;
}
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static void set_counter ( CUDAState * s , CUDATimer * ti , unsigned int val )
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{
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CUDA_DPRINTF ( "T%d.counter=%d \n " , 1 + ( ti -> timer == NULL ), val );
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ti -> load_time = qemu_get_clock ( vm_clock );
ti -> counter_value = val ;
cuda_timer_update ( s , ti , ti -> load_time );
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} static int64_t get_next_irq_time ( CUDATimer * s , int64_t current_time ) {
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int64_t d , next_time ;
unsigned int counter ;
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/* current counter value */
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d = muldiv64 ( current_time - s -> load_time ,
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CUDA_TIMER_FREQ , ticks_per_sec );
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/* the timer goes down from latch to -1 (period of latch + 2) */
if ( d <= ( s -> counter_value + 1 )) {
counter = ( s -> counter_value - d ) & 0xffff ;
} else {
counter = ( d - ( s -> counter_value + 1 )) % ( s -> latch + 2 );
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counter = ( s -> latch - counter ) & 0xffff ;
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}
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/* Note: we consider the irq is raised on 0 */
if ( counter == 0xffff ) {
next_time = d + s -> latch + 1 ;
} else if ( counter == 0 ) {
next_time = d + s -> latch + 2 ;
} else {
next_time = d + counter ;
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}
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CUDA_DPRINTF ( "latch=%d counter=%" PRId64 " delta_next=%" PRId64 " \n " ,
s -> latch , d , next_time - d );
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next_time = muldiv64 ( next_time , ticks_per_sec , CUDA_TIMER_FREQ ) +
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s -> load_time ;
if ( next_time <= current_time )
next_time = current_time + 1 ;
return next_time ;
}
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static void cuda_timer_update ( CUDAState * s , CUDATimer * ti ,
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int64_t current_time )
{ if ( ! ti -> timer )
return ;
if (( s -> acr & T1MODE ) != T1MODE_CONT ) {
qemu_del_timer ( ti -> timer );
} else {
ti -> next_irq_time = get_next_irq_time ( ti , current_time );
qemu_mod_timer ( ti -> timer , ti -> next_irq_time );
}
}
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static void cuda_timer1 ( void * opaque ) { CUDAState * s = opaque ;
CUDATimer * ti = & s -> timers [ 0 ];
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cuda_timer_update ( s , ti , ti -> next_irq_time );
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s -> ifr |= T1_INT ;
cuda_update_irq ( s );
} static uint32_t cuda_readb ( void * opaque , target_phys_addr_t addr ) { CUDAState * s = opaque ;
uint32_t val ;
addr = ( addr >> 9 ) & 0xf ;
switch ( addr ) {
case 0 :
val = s -> b ;
break ;
case 1 :
val = s -> a ;
break ;
case 2 :
val = s -> dirb ;
break ;
case 3 :
val = s -> dira ;
break ;
case 4 :
val = get_counter ( & s -> timers [ 0 ]) & 0xff ;
s -> ifr &= ~ T1_INT ;
cuda_update_irq ( s );
break ;
case 5 :
val = get_counter ( & s -> timers [ 0 ]) >> 8 ;
cuda_update_irq ( s );
break ;
case 6 :
val = s -> timers [ 0 ]. latch & 0xff ;
break ;
case 7 :
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/* XXX: check this */
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val = ( s -> timers [ 0 ]. latch >> 8 ) & 0xff ;
break ;
case 8 :
val = get_counter ( & s -> timers [ 1 ]) & 0xff ;
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s -> ifr &= ~ T2_INT ;
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break ;
case 9 :
val = get_counter ( & s -> timers [ 1 ]) >> 8 ;
break ;
case 10 :
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val = s -> sr ;
s -> ifr &= ~ SR_INT ;
cuda_update_irq ( s );
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break ;
case 11 :
val = s -> acr ;
break ;
case 12 :
val = s -> pcr ;
break ;
case 13 :
val = s -> ifr ;
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if ( s -> ifr & s -> ier )
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val |= 0x80 ;
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break ;
case 14 :
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val = s -> ier | 0x80 ;
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break ;
default :
case 15 :
val = s -> anh ;
break ;
}
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if ( addr != 13 || val != 0 )
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CUDA_DPRINTF ( "read: reg=0x%x val=%02x \n " , ( int ) addr , val );
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return val ;
} static void cuda_writeb ( void * opaque , target_phys_addr_t addr , uint32_t val ) { CUDAState * s = opaque ;
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addr = ( addr >> 9 ) & 0xf ;
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CUDA_DPRINTF ( "write: reg=0x%x val=%02x \n " , ( int ) addr , val );
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switch ( addr ) {
case 0 :
s -> b = val ;
cuda_update ( s );
break ;
case 1 :
s -> a = val ;
break ;
case 2 :
s -> dirb = val ;
break ;
case 3 :
s -> dira = val ;
break ;
case 4 :
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s -> timers [ 0 ]. latch = ( s -> timers [ 0 ]. latch & 0xff00 ) | val ;
cuda_timer_update ( s , & s -> timers [ 0 ], qemu_get_clock ( vm_clock ));
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break ;
case 5 :
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s -> timers [ 0 ]. latch = ( s -> timers [ 0 ]. latch & 0xff ) | ( val << 8 );
s -> ifr &= ~ T1_INT ;
set_counter ( s , & s -> timers [ 0 ], s -> timers [ 0 ]. latch );
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break ;
case 6 :
s -> timers [ 0 ]. latch = ( s -> timers [ 0 ]. latch & 0xff00 ) | val ;
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cuda_timer_update ( s , & s -> timers [ 0 ], qemu_get_clock ( vm_clock ));
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break ;
case 7 :
s -> timers [ 0 ]. latch = ( s -> timers [ 0 ]. latch & 0xff ) | ( val << 8 );
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s -> ifr &= ~ T1_INT ;
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cuda_timer_update ( s , & s -> timers [ 0 ], qemu_get_clock ( vm_clock ));
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break ;
case 8 :
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s -> timers [ 1 ]. latch = val ;
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set_counter ( s , & s -> timers [ 1 ], val );
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break ;
case 9 :
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set_counter ( s , & s -> timers [ 1 ], ( val << 8 ) | s -> timers [ 1 ]. latch );
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break ;
case 10 :
s -> sr = val ;
break ;
case 11 :
s -> acr = val ;
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cuda_timer_update ( s , & s -> timers [ 0 ], qemu_get_clock ( vm_clock ));
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cuda_update ( s );
break ;
case 12 :
s -> pcr = val ;
break ;
case 13 :
/* reset bits */
s -> ifr &= ~ val ;
cuda_update_irq ( s );
break ;
case 14 :
if ( val & IER_SET ) {
/* set bits */
s -> ier |= val & 0x7f ;
} else {
/* reset bits */
s -> ier &= ~ val ;
}
cuda_update_irq ( s );
break ;
default :
case 15 :
s -> anh = val ;
break ;
}
} /* NOTE: TIP and TREQ are negated */ static void cuda_update ( CUDAState * s ) {
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int packet_received , len ;
packet_received = 0 ;
if ( ! ( s -> b & TIP )) {
/* transfer requested from host */
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if ( s -> acr & SR_OUT ) {
/* data output */
if (( s -> b & ( TACK | TIP )) != ( s -> last_b & ( TACK | TIP ))) {
if ( s -> data_out_index < sizeof ( s -> data_out )) {
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CUDA_DPRINTF ( "send: %02x \n " , s -> sr );
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s -> data_out [ s -> data_out_index ++ ] = s -> sr ;
s -> ifr |= SR_INT ;
cuda_update_irq ( s );
}
}
} else {
if ( s -> data_in_index < s -> data_in_size ) {
/* data input */
if (( s -> b & ( TACK | TIP )) != ( s -> last_b & ( TACK | TIP ))) {
s -> sr = s -> data_in [ s -> data_in_index ++ ];
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CUDA_DPRINTF ( "recv: %02x \n " , s -> sr );
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/* indicate end of transfer */
if ( s -> data_in_index >= s -> data_in_size ) {
s -> b = ( s -> b | TREQ );
}
s -> ifr |= SR_INT ;
cuda_update_irq ( s );
}
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}
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}
} else {
/* no transfer requested: handle sync case */
if (( s -> last_b & TIP ) && ( s -> b & TACK ) != ( s -> last_b & TACK )) {
/* update TREQ state each time TACK change state */
if ( s -> b & TACK )
s -> b = ( s -> b | TREQ );
else
s -> b = ( s -> b & ~ TREQ );
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s -> ifr |= SR_INT ;
cuda_update_irq ( s );
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} else {
if ( ! ( s -> last_b & TIP )) {
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/* handle end of host to cuda transfer */
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packet_received = ( s -> data_out_index > 0 );
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/* always an IRQ at the end of transfer */
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s -> ifr |= SR_INT ;
cuda_update_irq ( s );
}
/* signal if there is data to read */
if ( s -> data_in_index < s -> data_in_size ) {
s -> b = ( s -> b & ~ TREQ );
}
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}
}
s -> last_acr = s -> acr ;
s -> last_b = s -> b ;
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/* NOTE : cuda_receive_packet_from_host () can call cuda_update ()
recursively */
if ( packet_received ) {
len = s -> data_out_index ;
s -> data_out_index = 0 ;
cuda_receive_packet_from_host ( s , s -> data_out , len );
}
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}
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static void cuda_send_packet_to_host ( CUDAState * s ,
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const uint8_t * data , int len )
{
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# ifdef DEBUG_CUDA_PACKET {
int i ;
printf ( "cuda_send_packet_to_host: \n " );
for ( i = 0 ; i < len ; i ++ )
printf ( " %02x" , data [ i ]);
printf ( " \n " );
}
# endif
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memcpy ( s -> data_in , data , len );
s -> data_in_size = len ;
s -> data_in_index = 0 ;
cuda_update ( s );
s -> ifr |= SR_INT ;
cuda_update_irq ( s );
}
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static void cuda_adb_poll ( void * opaque )
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{ CUDAState * s = opaque ;
uint8_t obuf [ ADB_MAX_OUT_LEN + 2 ];
int olen ;
olen = adb_poll ( & adb_bus , obuf + 2 );
if ( olen > 0 ) {
obuf [ 0 ] = ADB_PACKET ;
obuf [ 1 ] = 0x40 ; /* polled data */
cuda_send_packet_to_host ( s , obuf , olen + 2 );
}
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qemu_mod_timer ( s -> adb_poll_timer ,
qemu_get_clock ( vm_clock ) +
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( ticks_per_sec / CUDA_ADB_POLL_FREQ ));
}
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static void cuda_receive_packet ( CUDAState * s ,
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const uint8_t * data , int len )
{ uint8_t obuf [ 16 ];
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int autopoll ;
uint32_t ti ;
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switch ( data [ 0 ]) {
case CUDA_AUTOPOLL :
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autopoll = ( data [ 1 ] != 0 );
if ( autopoll != s -> autopoll ) {
s -> autopoll = autopoll ;
if ( autopoll ) {
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qemu_mod_timer ( s -> adb_poll_timer ,
qemu_get_clock ( vm_clock ) +
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( ticks_per_sec / CUDA_ADB_POLL_FREQ ));
} else {
qemu_del_timer ( s -> adb_poll_timer );
}
}
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obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = data [ 1 ];
cuda_send_packet_to_host ( s , obuf , 2 );
break ;
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case CUDA_SET_TIME :
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ti = ((( uint32_t ) data [ 1 ]) << 24 ) + ((( uint32_t ) data [ 2 ]) << 16 ) + ((( uint32_t ) data [ 3 ]) << 8 ) + data [ 4 ];
s -> tick_offset = ti - ( qemu_get_clock ( vm_clock ) / ticks_per_sec );
obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = 0 ;
obuf [ 2 ] = 0 ;
cuda_send_packet_to_host ( s , obuf , 3 );
break ;
case CUDA_GET_TIME :
ti = s -> tick_offset + ( qemu_get_clock ( vm_clock ) / ticks_per_sec );
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obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = 0 ;
obuf [ 2 ] = 0 ;
obuf [ 3 ] = ti >> 24 ;
obuf [ 4 ] = ti >> 16 ;
obuf [ 5 ] = ti >> 8 ;
obuf [ 6 ] = ti ;
cuda_send_packet_to_host ( s , obuf , 7 );
break ;
case CUDA_FILE_SERVER_FLAG :
case CUDA_SET_DEVICE_LIST :
case CUDA_SET_AUTO_RATE :
case CUDA_SET_POWER_MESSAGES :
obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = 0 ;
cuda_send_packet_to_host ( s , obuf , 2 );
break ;
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case CUDA_POWERDOWN :
obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = 0 ;
cuda_send_packet_to_host ( s , obuf , 2 );
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qemu_system_shutdown_request ();
break ;
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case CUDA_RESET_SYSTEM :
obuf [ 0 ] = CUDA_PACKET ;
obuf [ 1 ] = 0 ;
cuda_send_packet_to_host ( s , obuf , 2 );
qemu_system_reset_request ();
break ;
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default :
break ;
}
}
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static void cuda_receive_packet_from_host ( CUDAState * s ,
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const uint8_t * data , int len )
{
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# ifdef DEBUG_CUDA_PACKET {
int i ;
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printf ( "cuda_receive_packet_from_host: \n " );
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for ( i = 0 ; i < len ; i ++ )
printf ( " %02x" , data [ i ]);
printf ( " \n " );
}
# endif
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switch ( data [ 0 ]) {
case ADB_PACKET :
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{
uint8_t obuf [ ADB_MAX_OUT_LEN + 2 ];
int olen ;
olen = adb_request ( & adb_bus , obuf + 2 , data + 1 , len - 1 );
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if ( olen > 0 ) {
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obuf [ 0 ] = ADB_PACKET ;
obuf [ 1 ] = 0x00 ;
} else {
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/* error */
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obuf [ 0 ] = ADB_PACKET ;
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obuf [ 1 ] = - olen ;
olen = 0 ;
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}
cuda_send_packet_to_host ( s , obuf , olen + 2 );
}
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break ;
case CUDA_PACKET :
cuda_receive_packet ( s , data + 1 , len - 1 );
break ;
}
} static void cuda_writew ( void * opaque , target_phys_addr_t addr , uint32_t value ) { } static void cuda_writel ( void * opaque , target_phys_addr_t addr , uint32_t value ) { } static uint32_t cuda_readw ( void * opaque , target_phys_addr_t addr ) { return 0 ;
} static uint32_t cuda_readl ( void * opaque , target_phys_addr_t addr ) { return 0 ;
} static CPUWriteMemoryFunc * cuda_write [] = { & cuda_writeb ,
& cuda_writew ,
& cuda_writel ,
}; static CPUReadMemoryFunc * cuda_read [] = { & cuda_readb ,
& cuda_readw ,
& cuda_readl ,
};
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static void cuda_save_timer ( QEMUFile * f , CUDATimer * s ) { qemu_put_be16s ( f , & s -> latch );
qemu_put_be16s ( f , & s -> counter_value );
qemu_put_sbe64s ( f , & s -> load_time );
qemu_put_sbe64s ( f , & s -> next_irq_time );
if ( s -> timer )
qemu_put_timer ( f , s -> timer );
} static void cuda_save ( QEMUFile * f , void * opaque ) { CUDAState * s = ( CUDAState * ) opaque ;
qemu_put_ubyte ( f , s -> b );
qemu_put_ubyte ( f , s -> a );
qemu_put_ubyte ( f , s -> dirb );
qemu_put_ubyte ( f , s -> dira );
qemu_put_ubyte ( f , s -> sr );
qemu_put_ubyte ( f , s -> acr );
qemu_put_ubyte ( f , s -> pcr );
qemu_put_ubyte ( f , s -> ifr );
qemu_put_ubyte ( f , s -> ier );
qemu_put_ubyte ( f , s -> anh );
qemu_put_sbe32s ( f , & s -> data_in_size );
qemu_put_sbe32s ( f , & s -> data_in_index );
qemu_put_sbe32s ( f , & s -> data_out_index );
qemu_put_ubyte ( f , s -> autopoll );
qemu_put_buffer ( f , s -> data_in , sizeof ( s -> data_in ));
qemu_put_buffer ( f , s -> data_out , sizeof ( s -> data_out ));
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qemu_put_be32s ( f , & s -> tick_offset );
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cuda_save_timer ( f , & s -> timers [ 0 ]);
cuda_save_timer ( f , & s -> timers [ 1 ]);
} static void cuda_load_timer ( QEMUFile * f , CUDATimer * s ) { qemu_get_be16s ( f , & s -> latch );
qemu_get_be16s ( f , & s -> counter_value );
qemu_get_sbe64s ( f , & s -> load_time );
qemu_get_sbe64s ( f , & s -> next_irq_time );
if ( s -> timer )
qemu_get_timer ( f , s -> timer );
} static int cuda_load ( QEMUFile * f , void * opaque , int version_id ) { CUDAState * s = ( CUDAState * ) opaque ;
if ( version_id != 1 )
return - EINVAL ;
s -> b = qemu_get_ubyte ( f );
s -> a = qemu_get_ubyte ( f );
s -> dirb = qemu_get_ubyte ( f );
s -> dira = qemu_get_ubyte ( f );
s -> sr = qemu_get_ubyte ( f );
s -> acr = qemu_get_ubyte ( f );
s -> pcr = qemu_get_ubyte ( f );
s -> ifr = qemu_get_ubyte ( f );
s -> ier = qemu_get_ubyte ( f );
s -> anh = qemu_get_ubyte ( f );
qemu_get_sbe32s ( f , & s -> data_in_size );
qemu_get_sbe32s ( f , & s -> data_in_index );
qemu_get_sbe32s ( f , & s -> data_out_index );
s -> autopoll = qemu_get_ubyte ( f );
qemu_get_buffer ( f , s -> data_in , sizeof ( s -> data_in ));
qemu_get_buffer ( f , s -> data_out , sizeof ( s -> data_out ));
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qemu_get_be32s ( f , & s -> tick_offset );
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cuda_load_timer ( f , & s -> timers [ 0 ]);
cuda_load_timer ( f , & s -> timers [ 1 ]);
return 0 ;
}
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static void cuda_reset ( void * opaque ) { CUDAState * s = opaque ;
s -> b = 0 ;
s -> a = 0 ;
s -> dirb = 0 ;
s -> dira = 0 ;
s -> sr = 0 ;
s -> acr = 0 ;
s -> pcr = 0 ;
s -> ifr = 0 ;
s -> ier = 0 ;
// s -> ier = T1_INT | SR_INT ;
s -> anh = 0 ;
s -> data_in_size = 0 ;
s -> data_in_index = 0 ;
s -> data_out_index = 0 ;
s -> autopoll = 0 ;
s -> timers [ 0 ]. latch = 0xffff ;
set_counter ( s , & s -> timers [ 0 ], 0xffff );
s -> timers [ 1 ]. latch = 0 ;
set_counter ( s , & s -> timers [ 1 ], 0xffff );
}
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void cuda_init ( int * cuda_mem_index , qemu_irq irq )
748
{
749
struct tm tm ;
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CUDAState * s = & cuda_state ;
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s -> irq = irq ;
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s -> timers [ 0 ]. index = 0 ;
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s -> timers [ 0 ]. timer = qemu_new_timer ( vm_clock , cuda_timer1 , s );
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s -> timers [ 1 ]. index = 1 ;
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qemu_get_timedate ( & tm , 0 );
s -> tick_offset = ( uint32_t ) mktimegm ( & tm ) + RTC_OFFSET ;
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s -> adb_poll_timer = qemu_new_timer ( vm_clock , cuda_adb_poll , s );
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* cuda_mem_index = cpu_register_io_memory ( cuda_read , cuda_write , s );
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register_savevm ( "cuda" , - 1 , 1 , cuda_save , cuda_load , s );
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qemu_register_reset ( cuda_reset , s );
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cuda_reset ( s );
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}