/* * drivers/pcmcia/sa1100_neponset.c * * Neponset PCMCIA specific routines * */ #include #include #include #include #include #include #include static int neponset_pcmcia_init(struct pcmcia_init *init){ int return_val=0; /* Set GPIO_A<3:0> to be outputs for PCMCIA/CF power controller: */ PA_DDR &= ~(GPIO_GPIO0 | GPIO_GPIO1 | GPIO_GPIO2 | GPIO_GPIO3); /* MAX1600 to standby mode: */ PA_DWR &= ~(GPIO_GPIO0 | GPIO_GPIO1 | GPIO_GPIO2 | GPIO_GPIO3); NCR_0 &= ~(NCR_A0VPP | NCR_A1VPP); INTPOL1 |= (1 << (S0_READY_NINT - SA1111_IRQ(32))) | (1 << (S1_READY_NINT - SA1111_IRQ(32))) | (1 << (S0_CD_VALID - SA1111_IRQ(32))) | (1 << (S1_CD_VALID - SA1111_IRQ(32))) | (1 << (S0_BVD1_STSCHG - SA1111_IRQ(32))) | (1 << (S1_BVD1_STSCHG - SA1111_IRQ(32))); return_val+=request_irq(S0_CD_VALID, init->handler, SA_INTERRUPT, "Neponset PCMCIA (0) CD", NULL); return_val+=request_irq(S1_CD_VALID, init->handler, SA_INTERRUPT, "Neponset CF (1) CD", NULL); return_val+=request_irq(S0_BVD1_STSCHG, init->handler, SA_INTERRUPT, "Neponset PCMCIA (0) BVD1", NULL); return_val+=request_irq(S1_BVD1_STSCHG, init->handler, SA_INTERRUPT, "Neponset CF (1) BVD1", NULL); return (return_val<0) ? -1 : 2; } static int neponset_pcmcia_shutdown(void){ free_irq(S0_CD_VALID, NULL); free_irq(S1_CD_VALID, NULL); free_irq(S0_BVD1_STSCHG, NULL); free_irq(S1_BVD1_STSCHG, NULL); INTPOL1 &= ~((1 << (S0_CD_VALID - SA1111_IRQ(32))) | (1 << (S1_CD_VALID - SA1111_IRQ(32))) | (1 << (S0_BVD1_STSCHG - SA1111_IRQ(32))) | (1 << (S1_BVD1_STSCHG - SA1111_IRQ(32)))); return 0; } static int neponset_pcmcia_socket_state(struct pcmcia_state_array *state_array){ unsigned long status; int return_val=1; if(state_array->size<2) return -1; memset(state_array->state, 0, (state_array->size)*sizeof(struct pcmcia_state)); status=PCSR; state_array->state[0].detect=((status & PCSR_S0_DETECT)==0)?1:0; state_array->state[0].ready=((status & PCSR_S0_READY)==0)?0:1; state_array->state[0].bvd1=((status & PCSR_S0_BVD1)==0)?0:1; state_array->state[0].bvd2=((status & PCSR_S0_BVD2)==0)?0:1; state_array->state[0].wrprot=((status & PCSR_S0_WP)==0)?0:1; state_array->state[0].vs_3v=((status & PCSR_S0_VS1)==0)?1:0; state_array->state[0].vs_Xv=((status & PCSR_S0_VS2)==0)?1:0; state_array->state[1].detect=((status & PCSR_S1_DETECT)==0)?1:0; state_array->state[1].ready=((status & PCSR_S1_READY)==0)?0:1; state_array->state[1].bvd1=((status & PCSR_S1_BVD1)==0)?0:1; state_array->state[1].bvd2=((status & PCSR_S1_BVD2)==0)?0:1; state_array->state[1].wrprot=((status & PCSR_S1_WP)==0)?0:1; state_array->state[1].vs_3v=((status & PCSR_S1_VS1)==0)?1:0; state_array->state[1].vs_Xv=((status & PCSR_S1_VS2)==0)?1:0; return return_val; } static int neponset_pcmcia_get_irq_info(struct pcmcia_irq_info *info){ switch(info->sock){ case 0: info->irq=S0_READY_NINT; break; case 1: info->irq=S1_READY_NINT; break; default: return -1; } return 0; } static int neponset_pcmcia_configure_socket(const struct pcmcia_configure *configure){ unsigned long pccr=PCCR, ncr=NCR_0, gpio=PA_DWR; /* Neponset uses the Maxim MAX1600, with the following connections: * * MAX1600 Neponset * * A0VCC SA-1111 GPIO A<1> * A1VCC SA-1111 GPIO A<0> * A0VPP CPLD NCR A0VPP * A1VPP CPLD NCR A1VPP * B0VCC SA-1111 GPIO A<2> * B1VCC SA-1111 GPIO A<3> * B0VPP ground (slot B is CF) * B1VPP ground (slot B is CF) * * VX VCC (5V) * VY VCC3_3 (3.3V) * 12INA 12V * 12INB ground (slot B is CF) * * The MAX1600 CODE pin is tied to ground, placing the device in * "Standard Intel code" mode. Refer to the Maxim data sheet for * the corresponding truth table. */ switch(configure->sock){ case 0: switch(configure->vcc){ case 0: pccr=(pccr & ~PCCR_S0_FLT); gpio&=~(GPIO_GPIO0 | GPIO_GPIO1); break; case 33: pccr=(pccr & ~PCCR_S0_PSE) | PCCR_S0_FLT | PCCR_S0_PWAITEN; gpio=(gpio & ~(GPIO_GPIO0 | GPIO_GPIO1)) | GPIO_GPIO1; break; case 50: pccr=(pccr | PCCR_S0_PSE | PCCR_S0_FLT | PCCR_S0_PWAITEN); gpio=(gpio & ~(GPIO_GPIO0 | GPIO_GPIO1)) | GPIO_GPIO0; break; default: printk(KERN_ERR "%s(): unrecognized Vcc %u\n", __FUNCTION__, configure->vcc); return -1; } switch(configure->vpp){ case 0: ncr&=~(NCR_A0VPP | NCR_A1VPP); break; case 120: ncr=(ncr & ~(NCR_A0VPP | NCR_A1VPP)) | NCR_A1VPP; break; default: if(configure->vpp == configure->vcc) ncr=(ncr & ~(NCR_A0VPP | NCR_A1VPP)) | NCR_A0VPP; else { printk(KERN_ERR "%s(): unrecognized Vpp %u\n", __FUNCTION__, configure->vpp); return -1; } } pccr=(configure->reset)?(pccr | PCCR_S0_RST):(pccr & ~PCCR_S0_RST); break; case 1: switch(configure->vcc){ case 0: pccr=(pccr & ~PCCR_S1_FLT); gpio&=~(GPIO_GPIO2 | GPIO_GPIO3); break; case 33: pccr=(pccr & ~PCCR_S1_PSE) | PCCR_S1_FLT | PCCR_S1_PWAITEN; gpio=(gpio & ~(GPIO_GPIO2 | GPIO_GPIO3)) | GPIO_GPIO2; break; case 50: pccr=(pccr | PCCR_S1_PSE | PCCR_S1_FLT | PCCR_S1_PWAITEN); gpio=(gpio & ~(GPIO_GPIO2 | GPIO_GPIO3)) | GPIO_GPIO3; break; default: printk(KERN_ERR "%s(): unrecognized Vcc %u\n", __FUNCTION__, configure->vcc); return -1; } if(configure->vpp!=configure->vcc && configure->vpp!=0){ printk(KERN_ERR "%s(): CF slot cannot support Vpp %u\n", __FUNCTION__, configure->vpp); return -1; } pccr=(configure->reset)?(pccr | PCCR_S1_RST):(pccr & ~PCCR_S1_RST); break; default: return -1; } PCCR = pccr; NCR_0 = ncr; PA_DWR = gpio; return 0; } struct pcmcia_low_level neponset_pcmcia_ops = { neponset_pcmcia_init, neponset_pcmcia_shutdown, neponset_pcmcia_socket_state, neponset_pcmcia_get_irq_info, neponset_pcmcia_configure_socket };