Modify framebuffer and NGA framebuffer to read screen size from board model dtb file. Optimise memory usuage of frame buffer
Add example minigui application with hooks to profiler (which writes results to S:\). Modified NGA framebuffer to run its own dfc queue at high priority
/*
* CBUS three-pin bus and the Retu / Betty / Tahvo / Vilma / Avilma /
* Hinku / Vinku / Ahne / Pihi chips used in various Nokia platforms.
* Based on reverse-engineering of a linux driver.
*
* Copyright (C) 2008 Nokia Corporation
* Written by Andrzej Zaborowski <andrew@openedhand.com>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 or
* (at your option) version 3 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include "qemu-common.h"
#include "irq.h"
#include "devices.h"
#include "sysemu.h"
//#define DEBUG
struct cbus_slave_s;
struct cbus_priv_s {
struct cbus_s cbus;
int sel;
int dat;
int clk;
int bit;
int dir;
uint16_t val;
qemu_irq dat_out;
int addr;
int reg;
int rw;
enum {
cbus_address,
cbus_value,
} cycle;
struct cbus_slave_s *slave[8];
};
struct cbus_slave_s {
void *opaque;
void (*io)(void *opaque, int rw, int reg, uint16_t *val);
int addr;
};
static void cbus_io(struct cbus_priv_s *s)
{
if (s->slave[s->addr])
s->slave[s->addr]->io(s->slave[s->addr]->opaque,
s->rw, s->reg, &s->val);
else
cpu_abort(cpu_single_env, "%s: bad slave address %i\n",
__FUNCTION__, s->addr);
}
static void cbus_cycle(struct cbus_priv_s *s)
{
switch (s->cycle) {
case cbus_address:
s->addr = (s->val >> 6) & 7;
s->rw = (s->val >> 5) & 1;
s->reg = (s->val >> 0) & 0x1f;
s->cycle = cbus_value;
s->bit = 15;
s->dir = !s->rw;
s->val = 0;
if (s->rw)
cbus_io(s);
break;
case cbus_value:
if (!s->rw)
cbus_io(s);
s->cycle = cbus_address;
s->bit = 8;
s->dir = 1;
s->val = 0;
break;
}
}
static void cbus_clk(void *opaque, int line, int level)
{
struct cbus_priv_s *s = (struct cbus_priv_s *) opaque;
if (!s->sel && level && !s->clk) {
if (s->dir)
s->val |= s->dat << (s->bit --);
else
qemu_set_irq(s->dat_out, (s->val >> (s->bit --)) & 1);
if (s->bit < 0)
cbus_cycle(s);
}
s->clk = level;
}
static void cbus_dat(void *opaque, int line, int level)
{
struct cbus_priv_s *s = (struct cbus_priv_s *) opaque;
s->dat = level;
}
static void cbus_sel(void *opaque, int line, int level)
{
struct cbus_priv_s *s = (struct cbus_priv_s *) opaque;
if (!level) {
s->dir = 1;
s->bit = 8;
s->val = 0;
}
s->sel = level;
}
struct cbus_s *cbus_init(qemu_irq dat)
{
struct cbus_priv_s *s = (struct cbus_priv_s *) qemu_mallocz(sizeof(*s));
s->dat_out = dat;
s->cbus.clk = qemu_allocate_irqs(cbus_clk, s, 1)[0];
s->cbus.dat = qemu_allocate_irqs(cbus_dat, s, 1)[0];
s->cbus.sel = qemu_allocate_irqs(cbus_sel, s, 1)[0];
s->sel = 1;
s->clk = 0;
s->dat = 0;
return &s->cbus;
}
void cbus_attach(struct cbus_s *bus, void *slave_opaque)
{
struct cbus_slave_s *slave = (struct cbus_slave_s *) slave_opaque;
struct cbus_priv_s *s = (struct cbus_priv_s *) bus;
s->slave[slave->addr] = slave;
}
/* Retu/Vilma */
struct cbus_retu_s {
uint16_t irqst;
uint16_t irqen;
uint16_t cc[2];
int channel;
uint16_t result[16];
uint16_t sample;
uint16_t status;
struct {
uint16_t cal;
} rtc;
int is_vilma;
qemu_irq irq;
struct cbus_slave_s cbus;
};
static void retu_interrupt_update(struct cbus_retu_s *s)
{
qemu_set_irq(s->irq, s->irqst & ~s->irqen);
}
#define RETU_REG_ASICR 0x00 /* (RO) ASIC ID & revision */
#define RETU_REG_IDR 0x01 /* (T) Interrupt ID */
#define RETU_REG_IMR 0x02 /* (RW) Interrupt mask */
#define RETU_REG_RTCDSR 0x03 /* (RW) RTC seconds register */
#define RETU_REG_RTCHMR 0x04 /* (RO) RTC hours and minutes reg */
#define RETU_REG_RTCHMAR 0x05 /* (RW) RTC hours and minutes set reg */
#define RETU_REG_RTCCALR 0x06 /* (RW) RTC calibration register */
#define RETU_REG_ADCR 0x08 /* (RW) ADC result register */
#define RETU_REG_ADCSCR 0x09 /* (RW) ADC sample control register */
#define RETU_REG_AFCR 0x0a /* (RW) AFC register */
#define RETU_REG_ANTIFR 0x0b /* (RW) AntiF register */
#define RETU_REG_CALIBR 0x0c /* (RW) CalibR register*/
#define RETU_REG_CCR1 0x0d /* (RW) Common control register 1 */
#define RETU_REG_CCR2 0x0e /* (RW) Common control register 2 */
#define RETU_REG_RCTRL_CLR 0x0f /* (T) Regulator clear register */
#define RETU_REG_RCTRL_SET 0x10 /* (T) Regulator set register */
#define RETU_REG_TXCR 0x11 /* (RW) TxC register */
#define RETU_REG_STATUS 0x16 /* (RO) Status register */
#define RETU_REG_WATCHDOG 0x17 /* (RW) Watchdog register */
#define RETU_REG_AUDTXR 0x18 /* (RW) Audio Codec Tx register */
#define RETU_REG_AUDPAR 0x19 /* (RW) AudioPA register */
#define RETU_REG_AUDRXR1 0x1a /* (RW) Audio receive register 1 */
#define RETU_REG_AUDRXR2 0x1b /* (RW) Audio receive register 2 */
#define RETU_REG_SGR1 0x1c /* (RW) */
#define RETU_REG_SCR1 0x1d /* (RW) */
#define RETU_REG_SGR2 0x1e /* (RW) */
#define RETU_REG_SCR2 0x1f /* (RW) */
/* Retu Interrupt sources */
enum {
retu_int_pwr = 0, /* Power button */
retu_int_char = 1, /* Charger */
retu_int_rtcs = 2, /* Seconds */
retu_int_rtcm = 3, /* Minutes */
retu_int_rtcd = 4, /* Days */
retu_int_rtca = 5, /* Alarm */
retu_int_hook = 6, /* Hook */
retu_int_head = 7, /* Headset */
retu_int_adcs = 8, /* ADC sample */
};
/* Retu ADC channel wiring */
enum {
retu_adc_bsi = 1, /* BSI */
retu_adc_batt_temp = 2, /* Battery temperature */
retu_adc_chg_volt = 3, /* Charger voltage */
retu_adc_head_det = 4, /* Headset detection */
retu_adc_hook_det = 5, /* Hook detection */
retu_adc_rf_gp = 6, /* RF GP */
retu_adc_tx_det = 7, /* Wideband Tx detection */
retu_adc_batt_volt = 8, /* Battery voltage */
retu_adc_sens = 10, /* Light sensor */
retu_adc_sens_temp = 11, /* Light sensor temperature */
retu_adc_bbatt_volt = 12, /* Backup battery voltage */
retu_adc_self_temp = 13, /* RETU temperature */
};
static inline uint16_t retu_read(struct cbus_retu_s *s, int reg)
{
#ifdef DEBUG
printf("RETU read at %02x\n", reg);
#endif
switch (reg) {
case RETU_REG_ASICR:
return 0x0215 | (s->is_vilma << 7);
case RETU_REG_IDR: /* TODO: Or is this ffs(s->irqst)? */
return s->irqst;
case RETU_REG_IMR:
return s->irqen;
case RETU_REG_RTCDSR:
case RETU_REG_RTCHMR:
case RETU_REG_RTCHMAR:
/* TODO */
return 0x0000;
case RETU_REG_RTCCALR:
return s->rtc.cal;
case RETU_REG_ADCR:
return (s->channel << 10) | s->result[s->channel];
case RETU_REG_ADCSCR:
return s->sample;
case RETU_REG_AFCR:
case RETU_REG_ANTIFR:
case RETU_REG_CALIBR:
/* TODO */
return 0x0000;
case RETU_REG_CCR1:
return s->cc[0];
case RETU_REG_CCR2:
return s->cc[1];
case RETU_REG_RCTRL_CLR:
case RETU_REG_RCTRL_SET:
case RETU_REG_TXCR:
/* TODO */
return 0x0000;
case RETU_REG_STATUS:
return s->status;
case RETU_REG_WATCHDOG:
case RETU_REG_AUDTXR:
case RETU_REG_AUDPAR:
case RETU_REG_AUDRXR1:
case RETU_REG_AUDRXR2:
case RETU_REG_SGR1:
case RETU_REG_SCR1:
case RETU_REG_SGR2:
case RETU_REG_SCR2:
/* TODO */
return 0x0000;
default:
cpu_abort(cpu_single_env, "%s: bad register %02x\n",
__FUNCTION__, reg);
}
}
static inline void retu_write(struct cbus_retu_s *s, int reg, uint16_t val)
{
#ifdef DEBUG
printf("RETU write of %04x at %02x\n", val, reg);
#endif
switch (reg) {
case RETU_REG_IDR:
s->irqst ^= val;
retu_interrupt_update(s);
break;
case RETU_REG_IMR:
s->irqen = val;
retu_interrupt_update(s);
break;
case RETU_REG_RTCDSR:
case RETU_REG_RTCHMAR:
/* TODO */
break;
case RETU_REG_RTCCALR:
s->rtc.cal = val;
break;
case RETU_REG_ADCR:
s->channel = (val >> 10) & 0xf;
s->irqst |= 1 << retu_int_adcs;
retu_interrupt_update(s);
break;
case RETU_REG_ADCSCR:
s->sample &= ~val;
break;
case RETU_REG_AFCR:
case RETU_REG_ANTIFR:
case RETU_REG_CALIBR:
case RETU_REG_CCR1:
s->cc[0] = val;
break;
case RETU_REG_CCR2:
s->cc[1] = val;
break;
case RETU_REG_RCTRL_CLR:
case RETU_REG_RCTRL_SET:
/* TODO */
break;
case RETU_REG_WATCHDOG:
if (val == 0 && (s->cc[0] & 2))
qemu_system_shutdown_request();
break;
case RETU_REG_TXCR:
case RETU_REG_AUDTXR:
case RETU_REG_AUDPAR:
case RETU_REG_AUDRXR1:
case RETU_REG_AUDRXR2:
case RETU_REG_SGR1:
case RETU_REG_SCR1:
case RETU_REG_SGR2:
case RETU_REG_SCR2:
/* TODO */
break;
default:
cpu_abort(cpu_single_env, "%s: bad register %02x\n",
__FUNCTION__, reg);
}
}
static void retu_io(void *opaque, int rw, int reg, uint16_t *val)
{
struct cbus_retu_s *s = (struct cbus_retu_s *) opaque;
if (rw)
*val = retu_read(s, reg);
else
retu_write(s, reg, *val);
}
void *retu_init(qemu_irq irq, int vilma)
{
struct cbus_retu_s *s = (struct cbus_retu_s *) qemu_mallocz(sizeof(*s));
s->irq = irq;
s->irqen = 0xffff;
s->irqst = 0x0000;
s->status = 0x0020;
s->is_vilma = !!vilma;
s->rtc.cal = 0x01;
s->result[retu_adc_bsi] = 0x3c2;
s->result[retu_adc_batt_temp] = 0x0fc;
s->result[retu_adc_chg_volt] = 0x165;
s->result[retu_adc_head_det] = 123;
s->result[retu_adc_hook_det] = 1023;
s->result[retu_adc_rf_gp] = 0x11;
s->result[retu_adc_tx_det] = 0x11;
s->result[retu_adc_batt_volt] = 0x250;
s->result[retu_adc_sens] = 2;
s->result[retu_adc_sens_temp] = 0x11;
s->result[retu_adc_bbatt_volt] = 0x3d0;
s->result[retu_adc_self_temp] = 0x330;
s->cbus.opaque = s;
s->cbus.io = retu_io;
s->cbus.addr = 1;
return &s->cbus;
}
void retu_key_event(void *retu, int state)
{
struct cbus_slave_s *slave = (struct cbus_slave_s *) retu;
struct cbus_retu_s *s = (struct cbus_retu_s *) slave->opaque;
s->irqst |= 1 << retu_int_pwr;
retu_interrupt_update(s);
if (state)
s->status &= ~(1 << 5);
else
s->status |= 1 << 5;
}
#if 0
static void retu_head_event(void *retu, int state)
{
struct cbus_slave_s *slave = (struct cbus_slave_s *) retu;
struct cbus_retu_s *s = (struct cbus_retu_s *) slave->opaque;
if ((s->cc[0] & 0x500) == 0x500) { /* TODO: Which bits? */
/* TODO: reissue the interrupt every 100ms or so. */
s->irqst |= 1 << retu_int_head;
retu_interrupt_update(s);
}
if (state)
s->result[retu_adc_head_det] = 50;
else
s->result[retu_adc_head_det] = 123;
}
static void retu_hook_event(void *retu, int state)
{
struct cbus_slave_s *slave = (struct cbus_slave_s *) retu;
struct cbus_retu_s *s = (struct cbus_retu_s *) slave->opaque;
if ((s->cc[0] & 0x500) == 0x500) {
/* TODO: reissue the interrupt every 100ms or so. */
s->irqst |= 1 << retu_int_hook;
retu_interrupt_update(s);
}
if (state)
s->result[retu_adc_hook_det] = 50;
else
s->result[retu_adc_hook_det] = 123;
}
#endif
/* Tahvo/Betty */
struct cbus_tahvo_s {
uint16_t irqst;
uint16_t irqen;
uint8_t charger;
uint8_t backlight;
uint16_t usbr;
uint16_t power;
int is_betty;
qemu_irq irq;
struct cbus_slave_s cbus;
};
static void tahvo_interrupt_update(struct cbus_tahvo_s *s)
{
qemu_set_irq(s->irq, s->irqst & ~s->irqen);
}
#define TAHVO_REG_ASICR 0x00 /* (RO) ASIC ID & revision */
#define TAHVO_REG_IDR 0x01 /* (T) Interrupt ID */
#define TAHVO_REG_IDSR 0x02 /* (RO) Interrupt status */
#define TAHVO_REG_IMR 0x03 /* (RW) Interrupt mask */
#define TAHVO_REG_CHAPWMR 0x04 /* (RW) Charger PWM */
#define TAHVO_REG_LEDPWMR 0x05 /* (RW) LED PWM */
#define TAHVO_REG_USBR 0x06 /* (RW) USB control */
#define TAHVO_REG_RCR 0x07 /* (RW) Some kind of power management */
#define TAHVO_REG_CCR1 0x08 /* (RW) Common control register 1 */
#define TAHVO_REG_CCR2 0x09 /* (RW) Common control register 2 */
#define TAHVO_REG_TESTR1 0x0a /* (RW) Test register 1 */
#define TAHVO_REG_TESTR2 0x0b /* (RW) Test register 2 */
#define TAHVO_REG_NOPR 0x0c /* (RW) Number of periods */
#define TAHVO_REG_FRR 0x0d /* (RO) FR */
static inline uint16_t tahvo_read(struct cbus_tahvo_s *s, int reg)
{
#ifdef DEBUG
printf("TAHVO read at %02x\n", reg);
#endif
switch (reg) {
case TAHVO_REG_ASICR:
return 0x0021 | (s->is_betty ? 0x0b00 : 0x0300); /* 22 in N810 */
case TAHVO_REG_IDR:
case TAHVO_REG_IDSR: /* XXX: what does this do? */
return s->irqst;
case TAHVO_REG_IMR:
return s->irqen;
case TAHVO_REG_CHAPWMR:
return s->charger;
case TAHVO_REG_LEDPWMR:
return s->backlight;
case TAHVO_REG_USBR:
return s->usbr;
case TAHVO_REG_RCR:
return s->power;
case TAHVO_REG_CCR1:
case TAHVO_REG_CCR2:
case TAHVO_REG_TESTR1:
case TAHVO_REG_TESTR2:
case TAHVO_REG_NOPR:
case TAHVO_REG_FRR:
return 0x0000;
default:
cpu_abort(cpu_single_env, "%s: bad register %02x\n",
__FUNCTION__, reg);
}
}
static inline void tahvo_write(struct cbus_tahvo_s *s, int reg, uint16_t val)
{
#ifdef DEBUG
printf("TAHVO write of %04x at %02x\n", val, reg);
#endif
switch (reg) {
case TAHVO_REG_IDR:
s->irqst ^= val;
tahvo_interrupt_update(s);
break;
case TAHVO_REG_IMR:
s->irqen = val;
tahvo_interrupt_update(s);
break;
case TAHVO_REG_CHAPWMR:
s->charger = val;
break;
case TAHVO_REG_LEDPWMR:
if (s->backlight != (val & 0x7f)) {
s->backlight = val & 0x7f;
printf("%s: LCD backlight now at %i / 127\n",
__FUNCTION__, s->backlight);
}
break;
case TAHVO_REG_USBR:
s->usbr = val;
break;
case TAHVO_REG_RCR:
s->power = val;
break;
case TAHVO_REG_CCR1:
case TAHVO_REG_CCR2:
case TAHVO_REG_TESTR1:
case TAHVO_REG_TESTR2:
case TAHVO_REG_NOPR:
case TAHVO_REG_FRR:
break;
default:
cpu_abort(cpu_single_env, "%s: bad register %02x\n",
__FUNCTION__, reg);
}
}
static void tahvo_io(void *opaque, int rw, int reg, uint16_t *val)
{
struct cbus_tahvo_s *s = (struct cbus_tahvo_s *) opaque;
if (rw)
*val = tahvo_read(s, reg);
else
tahvo_write(s, reg, *val);
}
void *tahvo_init(qemu_irq irq, int betty)
{
struct cbus_tahvo_s *s = (struct cbus_tahvo_s *) qemu_mallocz(sizeof(*s));
s->irq = irq;
s->irqen = 0xffff;
s->irqst = 0x0000;
s->is_betty = !!betty;
s->cbus.opaque = s;
s->cbus.io = tahvo_io;
s->cbus.addr = 2;
return &s->cbus;
}