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fccpu30: updated to new LOG system

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This commit is contained in:
Joakim Larsson Edstrom 2017-02-10 14:41:36 +01:00
parent c2d117b559
commit cf83a2de29
2 changed files with 272 additions and 275 deletions
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513
src/devices/machine/fga002.cpp
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@ -31,27 +31,30 @@
* external hardware. It is expressly forbidden to change register bits, except those defined for the user.
*
*/
#define VERBOSE 0
//#define LOG_GENERAL (1U << 0)
#define LOG_SETUP (1U << 1)
#define LOG_READ (1U << 2)
#define LOG_INT (1U << 3)
#define LOG_VEC (1U << 4)
#define LOG_LVL (1U << 5)
#define LOG_IACK (1U << 6)
#define LOGPRINT(x) { do { if (VERBOSE) logerror x; } while (0); }
#define LOG(x) {} LOGPRINT(x)
#define LOGR(x) {} LOGPRINT(x)
#define LOGSETUP(x) {} LOGPRINT(x)
#define LOGINT(x) {} LOGPRINT(x)
#define LOGVEC(x) {} LOGPRINT(x)
#define LOGLVL(x) {} LOGPRINT(x)
#define LOGIACK(x) {} LOGPRINT(x)
//#define VERBOSE (LOG_GENERAL | LOG_SETUP)
//#define LOG_OUTPUT_FUNC printf
#if VERBOSE == 2
#define logerror printf
#endif
#include "logmacro.h"
#define LOGSETUP(...) LOGMASKED(LOG_SETUP, __VA_ARGS__)
#define LOGR(...) LOGMASKED(LOG_READ, __VA_ARGS__)
#define LOGINT(...) LOGMASKED(LOG_INT, __VA_ARGS__)
#define LOGVEC(...) LOGMASKED(LOG_VEC, __VA_ARGS__)
#define LOGLVL(...) LOGMASKED(LOG_LVL, __VA_ARGS__)
#define LOGIACK(...) LOGMASKED(LOG_IACK, __VA_ARGS__)
#ifdef _MSC_VER
#define FUNCNAME __func__
#define LLFORMAT "%I64%"
#else
#define FUNCNAME __PRETTY_FUNCTION__
#define LLFORMAT "%lld"
#endif
#include "fga002.h"
@ -98,7 +101,7 @@ fga002_device::fga002_device(const machine_config &mconfig, const char *tag, dev
void fga002_device::device_start()
{
LOG(("%s\n", FUNCNAME));
LOG("%s\n", FUNCNAME);
// resolve callbacks
m_out_int_cb.resolve_safe();
@ -118,7 +121,7 @@ void fga002_device::device_start()
void fga002_device::device_reset()
{
LOG(("%s\n", FUNCNAME));
LOG("%s\n", FUNCNAME);
/* Reset values for the FGA-002 */
memset(&m_fga002[0], 0, sizeof(m_fga002));
m_fga002[FGA_RSVMECALL] = 0x80;
@ -170,7 +173,7 @@ void fga002_device::device_timer (emu_timer &timer, device_timer_id id, int32_t
}
break;
default:
LOG(("Unhandled Timer ID %d\n", id));
LOG("Unhandled Timer ID %d\n", id);
break;
}
}
@ -229,7 +232,7 @@ void fga002_device::trigger_interrupt(uint8_t data)
{
uint8_t icr = 0;
LOGINT(("%s(%02x)\n", FUNCNAME, data));
LOGINT("%s(%02x)\n", FUNCNAME, data);
/* The Interrupt Control Register (ICR*) bit, must be set for the correspondning channel */
// TODO: Support programmable assert level for interrupt source
@ -243,15 +246,15 @@ void fga002_device::trigger_interrupt(uint8_t data)
case INT_LOCAL5: icr = m_fga002[FGA_ICRLOCAL5]; m_fga002[FGA_ISLOCAL5] = 0x00; break;
case INT_LOCAL6: icr = m_fga002[FGA_ICRLOCAL6]; m_fga002[FGA_ISLOCAL6] = 0x00; break;
case INT_LOCAL7: icr = m_fga002[FGA_ICRLOCAL7]; m_fga002[FGA_ISLOCAL7] = 0x00; break;
default: LOGINT((" - interrupt source %d - not supported", data)); return;
default: LOGINT(" - interrupt source %d - not supported", data); return;
}
if ((icr & REG_ICR_ENABLE) == 0 || (icr & REG_ICR_LVL_MSK) == 0)
{
LOGINT((" - The Interrupt Control Register bit for channel %02x is not set or level is 0, blocking attempt to interrupt\n", data));
LOGINT(" - The Interrupt Control Register bit for channel %02x is not set or level is 0, blocking attempt to interrupt\n", data);
return;
}
m_irq_level = icr & REG_ICR_LVL_MSK;
LOGINT((" - Interrupt Level %d, caused by ICR %02x with vector %02x\n", m_irq_level, icr, data ));
LOGINT(" - Interrupt Level %d, caused by ICR %02x with vector %02x\n", m_irq_level, icr, data );
// trigger intrrupt to CPU through board driver callback.
m_out_int_cb(ASSERT_LINE);
@ -263,30 +266,30 @@ IRQ_CALLBACK_MEMBER(fga002_device::iack)
int vec_found = 0;
int level;
LOGIACK(("%s %s()\n", tag(), FUNCNAME));
LOGIACK("%s %s()\n", tag(), FUNCNAME);
for (level = 7; level > 0; level--)
{
LOGLVL(("\n LEVEL %d\n", level));
LOGLVL("\n LEVEL %d\n", level);
// Find first interrupt on this level to acknowledge
LOGLVL(("Vec Status[val] Control[val]\n"));
LOGLVL("Vec Status[val] Control[val]\n");
for (auto & elem : m_irq_sources)
{
LOGLVL((" %02x %02x[%02x] %02x[%02x]\n",
LOGLVL(" %02x %02x[%02x] %02x[%02x]\n",
elem.vector,
elem.status, m_fga002[elem.status],
elem.control, m_fga002[elem.control]));
elem.control, m_fga002[elem.control]);
// Right level?
LOGLVL(("Level %02x == ICR %02x is %s\n", level, m_fga002[elem.control] & REG_ICR_LVL_MSK, ((m_fga002[elem.control] & REG_ICR_LVL_MSK) == level) ? "true!" : "false.."));
LOGLVL("Level %02x == ICR %02x is %s\n", level, m_fga002[elem.control] & REG_ICR_LVL_MSK, ((m_fga002[elem.control] & REG_ICR_LVL_MSK) == level) ? "true!" : "false..");
if ((m_fga002[elem.control] & REG_ICR_LVL_MSK) == level)
{
// Pending interrupt?
LOGLVL(("ISx %02x interrupt is %s\n", m_fga002[elem.status], (m_fga002[elem.status] & REG_ISLOCAL_IRQ) ? "cleared though.." : "pending!"));
LOGLVL("ISx %02x interrupt is %s\n", m_fga002[elem.status], (m_fga002[elem.status] & REG_ISLOCAL_IRQ) ? "cleared though.." : "pending!");
if ((m_fga002[elem.status] & REG_ISLOCAL_IRQ) == 0)
{
if (vec_found == 0)
{
vec = elem.vector; // Assume internal vector
LOGVEC((" - org vec:%02x ", vec));
LOGVEC(" - org vec:%02x ", vec);
switch (vec)
{
// Assuming that the attached device is returning -1 (INT_ACK_AUTOVECTOR) if no vector is provided, then we keep internal vector
@ -298,15 +301,15 @@ IRQ_CALLBACK_MEMBER(fga002_device::iack)
// All other devices uses the vector provided by the FGA.
default: break; /* Since we need the vector for the switch statement the default job is already done */
}
LOGVEC(("dev:%02x ", vec));
LOGVEC("dev:%02x ", vec);
if (vec == INT_ACK_AUTOVECTOR) vec = INT_EMPTY;
LOGVEC(("avec:%02x ", vec));
LOGVEC("avec:%02x ", vec);
// Add vector page bits and return vector
vec = (vec & 0x3f) | ((m_fga002[FGA_CTL3] & REG_CTL3_VECTORBITS7_6) << 4);
LOGVEC(("pvec:%02x\n", vec));
LOGVEC("pvec:%02x\n", vec);
LOGVEC((" - Interrupt Acknowledge Vector %02x\n", vec));
LOGVEC(" - Interrupt Acknowledge Vector %02x\n", vec);
/* TODO:
- Support auto clear of interrupt source and level triggered
*/
@ -314,7 +317,7 @@ IRQ_CALLBACK_MEMBER(fga002_device::iack)
}
else{
m_irq_level = level;
LOGIACK((" - Interrupt Acknowledge Vector %02x, next interrupt has level %02x\n", vec, m_irq_level));
LOGIACK(" - Interrupt Acknowledge Vector %02x, next interrupt has level %02x\n", vec, m_irq_level);
m_out_int_cb(CLEAR_LINE);
return vec;
}
@ -322,14 +325,14 @@ IRQ_CALLBACK_MEMBER(fga002_device::iack)
}
}
}
LOGIACK((" - Interrupt Acknowledge Vector %02x, next interrupt is off %02x\n", vec, m_irq_level));
LOGIACK(" - Interrupt Acknowledge Vector %02x, next interrupt is off %02x\n", vec, m_irq_level);
m_out_int_cb(CLEAR_LINE);
return vec;
}
int fga002_device::get_irq_level()
{
LOGINT(("%s %s() - %02x\n", tag(), FUNCNAME, m_irq_level));
LOGINT("%s %s() - %02x\n", tag(), FUNCNAME, m_irq_level);
return m_irq_level;
}
@ -356,13 +359,13 @@ int fga002_device::get_irq_level()
*/
void fga002_device::do_fga002reg_tim0preload_w(uint8_t data)
{
LOG(("%s(%02x)\n", FUNCNAME, data));
LOG("%s(%02x)\n", FUNCNAME, data);
m_fga002[FGA_TIM0PRELOAD] = data;
}
uint8_t fga002_device::do_fga002reg_tim0preload_r()
{
LOG(("%s() %02x\n", FUNCNAME, m_fga002[FGA_TIM0PRELOAD]));
LOG("%s() %02x\n", FUNCNAME, m_fga002[FGA_TIM0PRELOAD]);
return m_fga002[FGA_TIM0PRELOAD];
}
@ -408,7 +411,7 @@ uint8_t fga002_device::do_fga002reg_tim0preload_r()
void fga002_device::do_fga002reg_tim0ctl_w(uint8_t data)
{
LOG(("%s(%02x)\n", FUNCNAME, data));
LOG("%s(%02x)\n", FUNCNAME, data);
if ((data & REG_TIM0CTL_START_STOP) != (m_fga002[FGA_TIM0CTL] & REG_TIM0CTL_START_STOP))
{
if ((data & REG_TIM0CTL_START_STOP) == 0)
@ -443,7 +446,7 @@ void fga002_device::do_fga002reg_tim0ctl_w(uint8_t data)
uint8_t fga002_device::do_fga002reg_tim0ctl_r()
{
LOG(("%s() %02x\n", FUNCNAME, m_fga002[FGA_TIM0CTL]));
LOG("%s() %02x\n", FUNCNAME, m_fga002[FGA_TIM0CTL]);
return m_fga002[FGA_TIM0CTL];
}
@ -456,13 +459,13 @@ uint8_t fga002_device::do_fga002reg_tim0ctl_r()
*/
void fga002_device::do_fga002reg_tim0count_w(uint8_t data)
{
LOG(("%s(%02x)\n", FUNCNAME, data));
LOG("%s(%02x)\n", FUNCNAME, data);
m_tim0count = m_fga002[FGA_TIM0PRELOAD];
}
uint8_t fga002_device::do_fga002reg_tim0count_r()
{
LOG(("%s() %02x\n", FUNCNAME, m_tim0count));
LOG("%s() %02x\n", FUNCNAME, m_tim0count);
return m_tim0count;
}
@ -474,13 +477,13 @@ uint8_t fga002_device::do_fga002reg_tim0count_r()
*/
void fga002_device::do_fga002reg_icrtim0_w(uint8_t data)
{
LOGINT(("%s(%02x)\n", FUNCNAME, data));
LOGINT("%s(%02x)\n", FUNCNAME, data);
m_fga002[FGA_ICRTIM0] = data;
}
uint8_t fga002_device::do_fga002reg_icrtim0_r()
{
LOGINT(("%s() %02x\n", FUNCNAME, m_fga002[FGA_ICRTIM0]));
LOGINT("%s() %02x\n", FUNCNAME, m_fga002[FGA_ICRTIM0]);
return m_fga002[FGA_ICRTIM0];
}
@ -492,13 +495,13 @@ uint8_t fga002_device::do_fga002reg_icrtim0_r()
*/
void fga002_device::do_fga002reg_istim0_w(uint8_t data)
{
LOGINT(("%s(%02x)\n", FUNCNAME, data));
LOGINT("%s(%02x)\n", FUNCNAME, data);
m_fga002[FGA_ISTIM0] &= ~REG_ISTIM0_TIM_INT; // Clear timer interrupt status
}
uint8_t fga002_device::do_fga002reg_istim0_r()
{
LOGINT(("%s() %02x\n", FUNCNAME, m_fga002[FGA_ISTIM0]));
LOGINT("%s() %02x\n", FUNCNAME, m_fga002[FGA_ISTIM0]);
return m_fga002[FGA_ISTIM0];
}
@ -513,85 +516,85 @@ void fga002_device::do_fga002reg_localiack_w(uint8_t data)
#if VERBOSE
const char *liack[] = {"internal", "no", "external 1us", "external 500ns"};
LOGINT(("%s(%02x)\n", FUNCNAME, data));
LOGINT(("- LOCAL7: %s vector\n", liack[(data >> 6) & 0x03]));
LOGINT(("- LOCAL6: %s vector\n", liack[(data >> 4) & 0x03]));
LOGINT(("- LOCAL5: %s vector\n", liack[(data >> 2) & 0x03]));
LOGINT(("- LOCAL4: %s vector\n", liack[(data >> 0) & 0x03]));
LOGINT("%s(%02x)\n", FUNCNAME, data);
LOGINT("- LOCAL7: %s vector\n", liack[(data >> 6) & 0x03]);
LOGINT("- LOCAL6: %s vector\n", liack[(data >> 4) & 0x03]);
LOGINT("- LOCAL5: %s vector\n", liack[(data >> 2) & 0x03]);
LOGINT("- LOCAL4: %s vector\n", liack[(data >> 0) & 0x03]);
#endif
}
uint8_t fga002_device::do_fga002reg_localiack_r()
{
uint8_t ret = m_fga002[FGA_LOCALIACK];
LOGINT(("%s() <- %02x\n", FUNCNAME, ret));
LOGINT("%s() <- %02x\n", FUNCNAME, ret);
return ret;
}
uint8_t fga002_device::do_fga002reg_ctl3_r()
{
uint8_t ret = m_fga002[FGA_CTL3];
LOGINT(("%s() <- %02x\n", FUNCNAME, ret));
LOGINT("%s() <- %02x\n", FUNCNAME, ret);
return ret;
}
void fga002_device::do_fga002reg_ctl3_w(uint8_t data)
{
m_fga002[FGA_CTL3] = data;
LOGINT(("%s(%02x)\n", FUNCNAME, data));
LOGINT("%s(%02x)\n", FUNCNAME, data);
}
// Local Interrupt control register methods
uint8_t fga002_device::do_fga002reg_icrlocal0_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL0]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal1_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL1]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal2_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL2]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal3_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL3]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal4_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL4]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal5_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL5]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal6_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL6]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal7_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL7]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal0_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL0]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal1_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL1]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal2_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL2]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal3_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL3]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal4_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL4]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal5_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL5]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal6_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL6]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_icrlocal7_r(){ uint8_t ret = m_fga002[FGA_ICRLOCAL7]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
void fga002_device::do_fga002reg_icrlocal0_w(uint8_t data){ m_fga002[FGA_ICRLOCAL0] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal1_w(uint8_t data){ m_fga002[FGA_ICRLOCAL1] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal2_w(uint8_t data){ m_fga002[FGA_ICRLOCAL2] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal3_w(uint8_t data){ m_fga002[FGA_ICRLOCAL3] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal4_w(uint8_t data){ m_fga002[FGA_ICRLOCAL4] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal5_w(uint8_t data){ m_fga002[FGA_ICRLOCAL5] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal6_w(uint8_t data){ m_fga002[FGA_ICRLOCAL6] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal7_w(uint8_t data){ m_fga002[FGA_ICRLOCAL7] = data; LOGINT(("%s(%02x)\n", FUNCNAME, data)); }
void fga002_device::do_fga002reg_icrlocal0_w(uint8_t data){ m_fga002[FGA_ICRLOCAL0] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal1_w(uint8_t data){ m_fga002[FGA_ICRLOCAL1] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal2_w(uint8_t data){ m_fga002[FGA_ICRLOCAL2] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal3_w(uint8_t data){ m_fga002[FGA_ICRLOCAL3] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal4_w(uint8_t data){ m_fga002[FGA_ICRLOCAL4] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal5_w(uint8_t data){ m_fga002[FGA_ICRLOCAL5] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal6_w(uint8_t data){ m_fga002[FGA_ICRLOCAL6] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
void fga002_device::do_fga002reg_icrlocal7_w(uint8_t data){ m_fga002[FGA_ICRLOCAL7] = data; LOGINT("%s(%02x)\n", FUNCNAME, data); }
// Local Interrupt Status Register methods
uint8_t fga002_device::do_fga002reg_islocal0_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL0]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal1_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL1]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal2_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL2]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal3_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL3]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal4_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL4]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal5_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL5]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal6_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL6]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal7_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL7]; LOGINT(("%s() <- %02x\n", FUNCNAME, ret)); return ret; }
uint8_t fga002_device::do_fga002reg_islocal0_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL0]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal1_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL1]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal2_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL2]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal3_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL3]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal4_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL4]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal5_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL5]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal6_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL6]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
uint8_t fga002_device::do_fga002reg_islocal7_r(){ uint8_t ret = m_fga002[FGA_ISLOCAL7]; LOGINT("%s() <- %02x\n", FUNCNAME, ret); return ret; }
void fga002_device::islocal_w(int status, int vector, int control, int data)
{
m_fga002[status] = m_fga002[control] & REG_ICR_EDGE ? 0x80 : 0x00;
LOGINT(("%s(%02x)\n", FUNCNAME, m_fga002[status]));
LOGINT("%s(%02x)\n", FUNCNAME, m_fga002[status]);
}
// TODO: support level triggered interrupts, only edge triggered interrupts are supported atm
void fga002_device::do_fga002reg_islocal0_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL0, INT_LOCAL0, FGA_ICRLOCAL0, data ); }
void fga002_device::do_fga002reg_islocal1_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL1, INT_LOCAL1, FGA_ICRLOCAL1, data ); }
void fga002_device::do_fga002reg_islocal2_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL2, INT_LOCAL2, FGA_ICRLOCAL2, data ); }
void fga002_device::do_fga002reg_islocal3_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL3, INT_LOCAL3, FGA_ICRLOCAL3, data ); }
void fga002_device::do_fga002reg_islocal4_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL4, INT_LOCAL4, FGA_ICRLOCAL4, data ); m_liack4_cb(); } /* terminate device IRQ */
void fga002_device::do_fga002reg_islocal5_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL5, INT_LOCAL5, FGA_ICRLOCAL5, data ); m_liack5_cb(); }
void fga002_device::do_fga002reg_islocal6_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL6, INT_LOCAL6, FGA_ICRLOCAL6, data ); m_liack6_cb(); }
void fga002_device::do_fga002reg_islocal7_w(uint8_t data){ LOGINT(("%s\n", FUNCNAME)); islocal_w( FGA_ISLOCAL6, INT_LOCAL7, FGA_ICRLOCAL7, data ); m_liack7_cb(); }
void fga002_device::do_fga002reg_islocal0_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL0, INT_LOCAL0, FGA_ICRLOCAL0, data ); }
void fga002_device::do_fga002reg_islocal1_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL1, INT_LOCAL1, FGA_ICRLOCAL1, data ); }
void fga002_device::do_fga002reg_islocal2_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL2, INT_LOCAL2, FGA_ICRLOCAL2, data ); }
void fga002_device::do_fga002reg_islocal3_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL3, INT_LOCAL3, FGA_ICRLOCAL3, data ); }
void fga002_device::do_fga002reg_islocal4_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL4, INT_LOCAL4, FGA_ICRLOCAL4, data ); m_liack4_cb(); } /* terminate device IRQ */
void fga002_device::do_fga002reg_islocal5_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL5, INT_LOCAL5, FGA_ICRLOCAL5, data ); m_liack5_cb(); }
void fga002_device::do_fga002reg_islocal6_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL6, INT_LOCAL6, FGA_ICRLOCAL6, data ); m_liack6_cb(); }
void fga002_device::do_fga002reg_islocal7_w(uint8_t data){ LOGINT("%s\n", FUNCNAME); islocal_w( FGA_ISLOCAL6, INT_LOCAL7, FGA_ICRLOCAL7, data ); m_liack7_cb(); }
// Local IRQ callbacks
// TODO: support level triggered interrupts, ICR bit 6, only edge triggered interrupts are supported atm
// TODO: support programmable assertion levels ICR bit 5, a call to this function assumes assertion atm
void fga002_device::lirq_w(int status, int vector, int control, int state)
{
LOGINT((" - %s\n", state == ASSERT_LINE ? "Asserted" : "Cleared"));
LOGINT(" - %s\n", state == ASSERT_LINE ? "Asserted" : "Cleared");
if (state == ASSERT_LINE)
{
m_fga002[status] &= ~REG_ISLOCAL_IRQ;
@ -603,64 +606,64 @@ void fga002_device::lirq_w(int status, int vector, int control, int state)
}
}
WRITE_LINE_MEMBER (fga002_device::lirq0_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL0, INT_LOCAL0, FGA_ICRLOCAL0, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq1_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL1, INT_LOCAL1, FGA_ICRLOCAL1, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq2_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL2, INT_LOCAL2, FGA_ICRLOCAL2, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq3_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL3, INT_LOCAL3, FGA_ICRLOCAL3, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq4_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL4, INT_LOCAL4, FGA_ICRLOCAL4, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq5_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL5, INT_LOCAL5, FGA_ICRLOCAL5, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq6_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL6, INT_LOCAL6, FGA_ICRLOCAL6, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq7_w) { LOGINT(("%s\n", FUNCNAME)); lirq_w( FGA_ISLOCAL7, INT_LOCAL7, FGA_ICRLOCAL7, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq0_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL0, INT_LOCAL0, FGA_ICRLOCAL0, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq1_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL1, INT_LOCAL1, FGA_ICRLOCAL1, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq2_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL2, INT_LOCAL2, FGA_ICRLOCAL2, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq3_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL3, INT_LOCAL3, FGA_ICRLOCAL3, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq4_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL4, INT_LOCAL4, FGA_ICRLOCAL4, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq5_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL5, INT_LOCAL5, FGA_ICRLOCAL5, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq6_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL6, INT_LOCAL6, FGA_ICRLOCAL6, state ); }
WRITE_LINE_MEMBER (fga002_device::lirq7_w) { LOGINT("%s\n", FUNCNAME); lirq_w( FGA_ISLOCAL7, INT_LOCAL7, FGA_ICRLOCAL7, state ); }
WRITE8_MEMBER (fga002_device::write){
LOG(("%s[%04x] <- %02x - ", FUNCNAME, offset, data));
LOGSETUP((" * %s Reg %04x <- %02x\n", tag(), offset, data));
LOG("%s[%04x] <- %02x - ", FUNCNAME, offset, data);
LOGSETUP(" * %s Reg %04x <- %02x\n", tag(), offset, data);
switch(offset)
{
case FGA_SPECIALENA : LOG(("FGA_SPECIALENA - not implemented\n")); m_fga002[FGA_SPECIALENA] = data; break;
case FGA_RSVMECALL : LOG(("FGA_RSVMECALL - not implemented\n")); m_fga002[FGA_RSVMECALL] = data; break;
case FGA_RSKEYRES : LOG(("FGA_RSKEYRES - not implemented\n")); m_fga002[FGA_RSKEYRES] = data; break;
case FGA_RSCPUCALL : LOG(("FGA_RSCPUCALL - not implemented\n")); m_fga002[FGA_RSCPUCALL] = data; break;
case FGA_RSLOCSW : LOG(("FGA_RSLOCSW - not implemented\n")); m_fga002[FGA_RSLOCSW] = data; break;
case FGA_ICRMBOX0 : LOG(("FGA_ICRMBOX0 - not implemented\n")); m_fga002[FGA_ICRMBOX0] = data; break;
case FGA_ICRMBOX1 : LOG(("FGA_ICRMBOX1 - not implemented\n")); m_fga002[FGA_ICRMBOX1] = data; break;
case FGA_ICRMBOX2 : LOG(("FGA_ICRMBOX2 - not implemented\n")); m_fga002[FGA_ICRMBOX2] = data; break;
case FGA_ICRMBOX3 : LOG(("FGA_ICRMBOX3 - not implemented\n")); m_fga002[FGA_ICRMBOX3] = data; break;
case FGA_ICRMBOX4 : LOG(("FGA_ICRMBOX4 - not implemented\n")); m_fga002[FGA_ICRMBOX4] = data; break;
case FGA_ICRMBOX5 : LOG(("FGA_ICRMBOX5 - not implemented\n")); m_fga002[FGA_ICRMBOX5] = data; break;
case FGA_ICRMBOX6 : LOG(("FGA_ICRMBOX6 - not implemented\n")); m_fga002[FGA_ICRMBOX6] = data; break;
case FGA_ICRMBOX7 : LOG(("FGA_ICRMBOX7 - not implemented\n")); m_fga002[FGA_ICRMBOX7] = data; break;
case FGA_VMEPAGE : LOG(("FGA_VMEPAGE - not implemented\n")); m_fga002[FGA_VMEPAGE ] = data; break;
case FGA_ICRVME1 : LOG(("FGA_ICRVME1 - not implemented\n")); m_fga002[FGA_ICRVME1] = data; break;
case FGA_ICRVME2 : LOG(("FGA_ICRVME2 - not implemented\n")); m_fga002[FGA_ICRVME2] = data; break;
case FGA_ICRVME3 : LOG(("FGA_ICRVME3 - not implemented\n")); m_fga002[FGA_ICRVME3] = data; break;
case FGA_ICRVME4 : LOG(("FGA_ICRVME4 - not implemented\n")); m_fga002[FGA_ICRVME4] = data; break;
case FGA_ICRVME5 : LOG(("FGA_ICRVME5 - not implemented\n")); m_fga002[FGA_ICRVME5] = data; break;
case FGA_ICRVME6 : LOG(("FGA_ICRVME6 - not implemented\n")); m_fga002[FGA_ICRVME6] = data; break;
case FGA_ICRVME7 : LOG(("FGA_ICRVME7 - not implemented\n")); m_fga002[FGA_ICRVME7] = data; break;
case FGA_SPECIALENA : LOG("FGA_SPECIALENA - not implemented\n"); m_fga002[FGA_SPECIALENA] = data; break;
case FGA_RSVMECALL : LOG("FGA_RSVMECALL - not implemented\n"); m_fga002[FGA_RSVMECALL] = data; break;
case FGA_RSKEYRES : LOG("FGA_RSKEYRES - not implemented\n"); m_fga002[FGA_RSKEYRES] = data; break;
case FGA_RSCPUCALL : LOG("FGA_RSCPUCALL - not implemented\n"); m_fga002[FGA_RSCPUCALL] = data; break;
case FGA_RSLOCSW : LOG("FGA_RSLOCSW - not implemented\n"); m_fga002[FGA_RSLOCSW] = data; break;
case FGA_ICRMBOX0 : LOG("FGA_ICRMBOX0 - not implemented\n"); m_fga002[FGA_ICRMBOX0] = data; break;
case FGA_ICRMBOX1 : LOG("FGA_ICRMBOX1 - not implemented\n"); m_fga002[FGA_ICRMBOX1] = data; break;
case FGA_ICRMBOX2 : LOG("FGA_ICRMBOX2 - not implemented\n"); m_fga002[FGA_ICRMBOX2] = data; break;
case FGA_ICRMBOX3 : LOG("FGA_ICRMBOX3 - not implemented\n"); m_fga002[FGA_ICRMBOX3] = data; break;
case FGA_ICRMBOX4 : LOG("FGA_ICRMBOX4 - not implemented\n"); m_fga002[FGA_ICRMBOX4] = data; break;
case FGA_ICRMBOX5 : LOG("FGA_ICRMBOX5 - not implemented\n"); m_fga002[FGA_ICRMBOX5] = data; break;
case FGA_ICRMBOX6 : LOG("FGA_ICRMBOX6 - not implemented\n"); m_fga002[FGA_ICRMBOX6] = data; break;
case FGA_ICRMBOX7 : LOG("FGA_ICRMBOX7 - not implemented\n"); m_fga002[FGA_ICRMBOX7] = data; break;
case FGA_VMEPAGE : LOG("FGA_VMEPAGE - not implemented\n"); m_fga002[FGA_VMEPAGE ] = data; break;
case FGA_ICRVME1 : LOG("FGA_ICRVME1 - not implemented\n"); m_fga002[FGA_ICRVME1] = data; break;
case FGA_ICRVME2 : LOG("FGA_ICRVME2 - not implemented\n"); m_fga002[FGA_ICRVME2] = data; break;
case FGA_ICRVME3 : LOG("FGA_ICRVME3 - not implemented\n"); m_fga002[FGA_ICRVME3] = data; break;
case FGA_ICRVME4 : LOG("FGA_ICRVME4 - not implemented\n"); m_fga002[FGA_ICRVME4] = data; break;
case FGA_ICRVME5 : LOG("FGA_ICRVME5 - not implemented\n"); m_fga002[FGA_ICRVME5] = data; break;
case FGA_ICRVME6 : LOG("FGA_ICRVME6 - not implemented\n"); m_fga002[FGA_ICRVME6] = data; break;
case FGA_ICRVME7 : LOG("FGA_ICRVME7 - not implemented\n"); m_fga002[FGA_ICRVME7] = data; break;
case FGA_ICRTIM0 : do_fga002reg_icrtim0_w(data); break;
case FGA_ICRDMANORM : LOG(("FGA_ICRDMANORM - not implemented\n")); m_fga002[FGA_ICRDMANORM] = data; break;
case FGA_ICRDMAERR : LOG(("FGA_ICRDMAERR - not implemented\n")); m_fga002[FGA_ICRDMAERR] = data; break;
case FGA_CTL1 : LOG(("FGA_CTL1 - not implemented\n")); m_fga002[FGA_CTL1] = data; break;
case FGA_CTL2 : LOG(("FGA_CTL2 - not implemented\n")); m_fga002[FGA_CTL2] = data; break;
case FGA_ICRFMB0REF : LOG(("FGA_ICRFMB0REF - not implemented\n")); m_fga002[FGA_ICRFMB0REF] = data; break;
case FGA_ICRFMB1REF : LOG(("FGA_ICRFMB1REF - not implemented\n")); m_fga002[FGA_ICRFMB1REF] = data; break;
case FGA_ICRFMB0MES : LOG(("FGA_ICRFMB0MES - not implemented\n")); m_fga002[FGA_ICRFMB0MES] = data; break;
case FGA_ICRFMB1MES : LOG(("FGA_ICRFMB1MES - not implemented\n")); m_fga002[FGA_ICRFMB1MES] = data; break;
case FGA_ICRDMANORM : LOG("FGA_ICRDMANORM - not implemented\n"); m_fga002[FGA_ICRDMANORM] = data; break;
case FGA_ICRDMAERR : LOG("FGA_ICRDMAERR - not implemented\n"); m_fga002[FGA_ICRDMAERR] = data; break;
case FGA_CTL1 : LOG("FGA_CTL1 - not implemented\n"); m_fga002[FGA_CTL1] = data; break;
case FGA_CTL2 : LOG("FGA_CTL2 - not implemented\n"); m_fga002[FGA_CTL2] = data; break;
case FGA_ICRFMB0REF : LOG("FGA_ICRFMB0REF - not implemented\n"); m_fga002[FGA_ICRFMB0REF] = data; break;
case FGA_ICRFMB1REF : LOG("FGA_ICRFMB1REF - not implemented\n"); m_fga002[FGA_ICRFMB1REF] = data; break;
case FGA_ICRFMB0MES : LOG("FGA_ICRFMB0MES - not implemented\n"); m_fga002[FGA_ICRFMB0MES] = data; break;
case FGA_ICRFMB1MES : LOG("FGA_ICRFMB1MES - not implemented\n"); m_fga002[FGA_ICRFMB1MES] = data; break;
case FGA_CTL3 : do_fga002reg_ctl3_w(data); break;
case FGA_CTL4 : LOG(("FGA_CTL4 - not implemented\n")); m_fga002[FGA_CTL4] = data; break;
case FGA_ICRPARITY : LOG(("FGA_ICRPARITY - not implemented\n")); m_fga002[FGA_ICRPARITY] = data; break;
case FGA_AUXPINCTL : LOG(("FGA_AUXPINCTL - not implemented\n")); m_fga002[FGA_AUXPINCTL] = data; break;
case FGA_CTL5 : LOG(("FGA_CTL5 - not implemented\n")); m_fga002[FGA_CTL5] = data; break;
case FGA_AUXFIFWEX : LOG(("FGA_AUXFIFWEX - not implemented\n")); m_fga002[FGA_AUXFIFWEX] = data; break;
case FGA_AUXFIFREX : LOG(("FGA_AUXFIFREX - not implemented\n")); m_fga002[FGA_AUXFIFREX] = data; break;
case FGA_CTL6 : LOG(("FGA_CTL6 - not implemented\n")); m_fga002[FGA_CTL6] = data; break;
case FGA_CTL7 : LOG(("FGA_CTL7 - not implemented\n")); m_fga002[FGA_CTL7] = data; break;
case FGA_CTL8 : LOG(("FGA_CTL8 - not implemented\n")); m_fga002[FGA_CTL8] = data; break;
case FGA_CTL9 : LOG(("FGA_CTL9 - not implemented\n")); m_fga002[FGA_CTL9] = data; break;
case FGA_ICRABORT : LOG(("FGA_ICRABORT - not implemented\n")); m_fga002[FGA_ICRABORT] = data; break;
case FGA_ICRACFAIL : LOG(("FGA_ICRACFAIL - not implemented\n")); m_fga002[FGA_ICRACFAIL] = data; break;
case FGA_ICRSYSFAIL : LOG(("FGA_ICRSYSFAIL - not implemented\n")); m_fga002[FGA_ICRSYSFAIL] = data; break;
case FGA_CTL4 : LOG("FGA_CTL4 - not implemented\n"); m_fga002[FGA_CTL4] = data; break;
case FGA_ICRPARITY : LOG("FGA_ICRPARITY - not implemented\n"); m_fga002[FGA_ICRPARITY] = data; break;
case FGA_AUXPINCTL : LOG("FGA_AUXPINCTL - not implemented\n"); m_fga002[FGA_AUXPINCTL] = data; break;
case FGA_CTL5 : LOG("FGA_CTL5 - not implemented\n"); m_fga002[FGA_CTL5] = data; break;
case FGA_AUXFIFWEX : LOG("FGA_AUXFIFWEX - not implemented\n"); m_fga002[FGA_AUXFIFWEX] = data; break;
case FGA_AUXFIFREX : LOG("FGA_AUXFIFREX - not implemented\n"); m_fga002[FGA_AUXFIFREX] = data; break;
case FGA_CTL6 : LOG("FGA_CTL6 - not implemented\n"); m_fga002[FGA_CTL6] = data; break;
case FGA_CTL7 : LOG("FGA_CTL7 - not implemented\n"); m_fga002[FGA_CTL7] = data; break;
case FGA_CTL8 : LOG("FGA_CTL8 - not implemented\n"); m_fga002[FGA_CTL8] = data; break;
case FGA_CTL9 : LOG("FGA_CTL9 - not implemented\n"); m_fga002[FGA_CTL9] = data; break;
case FGA_ICRABORT : LOG("FGA_ICRABORT - not implemented\n"); m_fga002[FGA_ICRABORT] = data; break;
case FGA_ICRACFAIL : LOG("FGA_ICRACFAIL - not implemented\n"); m_fga002[FGA_ICRACFAIL] = data; break;
case FGA_ICRSYSFAIL : LOG("FGA_ICRSYSFAIL - not implemented\n"); m_fga002[FGA_ICRSYSFAIL] = data; break;
case FGA_ICRLOCAL0 : do_fga002reg_icrlocal0_w(data); break;
case FGA_ICRLOCAL1 : do_fga002reg_icrlocal1_w(data); break;
case FGA_ICRLOCAL2 : do_fga002reg_icrlocal2_w(data); break;
@ -669,34 +672,34 @@ WRITE8_MEMBER (fga002_device::write){
case FGA_ICRLOCAL5 : do_fga002reg_icrlocal5_w(data); break;
case FGA_ICRLOCAL6 : do_fga002reg_icrlocal6_w(data); break;
case FGA_ICRLOCAL7 : do_fga002reg_icrlocal7_w(data); break;
case FGA_ENAMCODE : LOG(("FGA_ENAMCODE - not implemented\n")); m_fga002[FGA_ENAMCODE] = data; break;
case FGA_CTL10 : LOG(("FGA_CTL10 - not implemented\n")); m_fga002[FGA_CTL10] = data; break;
case FGA_CTL11 : LOG(("FGA_CTL11 - not implemented\n")); m_fga002[FGA_CTL11] = data; break;
case FGA_MAINUM : LOG(("FGA_MAINUM - not implemented\n")); m_fga002[FGA_MAINUM] = data; break;
case FGA_MAINUU : LOG(("FGA_MAINUU - not implemented\n")); m_fga002[FGA_MAINUU] = data; break;
case FGA_BOTTOMPAGEU : LOG(("FGA_BOTTOMPAGEU - not implemented\n")); m_fga002[FGA_BOTTOMPAGEU] = data; break;
case FGA_BOTTOMPAGEL : LOG(("FGA_BOTTOMPAGEL - not implemented\n")); m_fga002[FGA_BOTTOMPAGEL] = data; break;
case FGA_TOPPAGEU : LOG(("FGA_TOPPAGEU - not implemented\n")); m_fga002[FGA_TOPPAGEU] = data; break;
case FGA_TOPPAGEL : LOG(("FGA_TOPPAGEL - not implemented\n")); m_fga002[FGA_TOPPAGEL] = data; break;
case FGA_MYVMEPAGE : LOG(("FGA_MYVMEPAGE - not implemented\n")); m_fga002[FGA_MYVMEPAGE] = data; break;
case FGA_ENAMCODE : LOG("FGA_ENAMCODE - not implemented\n"); m_fga002[FGA_ENAMCODE] = data; break;
case FGA_CTL10 : LOG("FGA_CTL10 - not implemented\n"); m_fga002[FGA_CTL10] = data; break;
case FGA_CTL11 : LOG("FGA_CTL11 - not implemented\n"); m_fga002[FGA_CTL11] = data; break;
case FGA_MAINUM : LOG("FGA_MAINUM - not implemented\n"); m_fga002[FGA_MAINUM] = data; break;
case FGA_MAINUU : LOG("FGA_MAINUU - not implemented\n"); m_fga002[FGA_MAINUU] = data; break;
case FGA_BOTTOMPAGEU : LOG("FGA_BOTTOMPAGEU - not implemented\n"); m_fga002[FGA_BOTTOMPAGEU] = data; break;
case FGA_BOTTOMPAGEL : LOG("FGA_BOTTOMPAGEL - not implemented\n"); m_fga002[FGA_BOTTOMPAGEL] = data; break;
case FGA_TOPPAGEU : LOG("FGA_TOPPAGEU - not implemented\n"); m_fga002[FGA_TOPPAGEU] = data; break;
case FGA_TOPPAGEL : LOG("FGA_TOPPAGEL - not implemented\n"); m_fga002[FGA_TOPPAGEL] = data; break;
case FGA_MYVMEPAGE : LOG("FGA_MYVMEPAGE - not implemented\n"); m_fga002[FGA_MYVMEPAGE] = data; break;
case FGA_TIM0PRELOAD : do_fga002reg_tim0preload_w(data); break;
case FGA_TIM0CTL : do_fga002reg_tim0ctl_w(data); break;
case FGA_DMASRCATT : LOG(("FGA_DMASRCATT - not implemented\n")); m_fga002[FGA_DMASRCATT] = data; break;
case FGA_DMADSTATT : LOG(("FGA_DMADSTATT - not implemented\n")); m_fga002[FGA_DMADSTATT] = data; break;
case FGA_DMA_GENERAL : LOG(("FGA_DMA_GENERAL - not implemented\n")); m_fga002[FGA_DMA_GENERAL] = data; break;
case FGA_CTL12 : LOG(("FGA_CTL12 - not implemented\n")); m_fga002[FGA_CTL12] = data; break;
case FGA_LIOTIMING : LOG(("FGA_LIOTIMING - not implemented\n")); m_fga002[FGA_LIOTIMING] = data; break;
case FGA_DMASRCATT : LOG("FGA_DMASRCATT - not implemented\n"); m_fga002[FGA_DMASRCATT] = data; break;
case FGA_DMADSTATT : LOG("FGA_DMADSTATT - not implemented\n"); m_fga002[FGA_DMADSTATT] = data; break;
case FGA_DMA_GENERAL : LOG("FGA_DMA_GENERAL - not implemented\n"); m_fga002[FGA_DMA_GENERAL] = data; break;
case FGA_CTL12 : LOG("FGA_CTL12 - not implemented\n"); m_fga002[FGA_CTL12] = data; break;
case FGA_LIOTIMING : LOG("FGA_LIOTIMING - not implemented\n"); m_fga002[FGA_LIOTIMING] = data; break;
case FGA_LOCALIACK : do_fga002reg_localiack_w(data);
case FGA_FMBCTL : LOG(("FGA_FMBCTL - not implemented\n")); m_fga002[FGA_FMBCTL] = data; break;
case FGA_FMBAREA : LOG(("FGA_FMBAREA - not implemented\n")); m_fga002[FGA_FMBAREA] = data; break;
case FGA_AUXSRCSTART : LOG(("FGA_AUXSRCSTART - not implemented\n")); m_fga002[FGA_AUXSRCSTART] = data; break;
case FGA_AUXDSTSTART : LOG(("FGA_AUXDSTSTART - not implemented\n")); m_fga002[FGA_AUXDSTSTART] = data; break;
case FGA_AUXSRCTERM : LOG(("FGA_AUXSRCTERM - not implemented\n")); m_fga002[FGA_AUXSRCTERM] = data; break;
case FGA_AUXDSTTERM : LOG(("FGA_AUXDSTTERM - not implemented\n")); m_fga002[FGA_AUXDSTTERM] = data; break;
case FGA_CTL13 : LOG(("FGA_CTL13 - not implemented\n")); m_fga002[FGA_CTL13] = data; break;
case FGA_CTL14 : LOG(("FGA_CTL14 - not implemented\n")); m_fga002[FGA_CTL14] = data; break;
case FGA_CTL15 : LOG(("FGA_CTL15 - not implemented\n")); m_fga002[FGA_CTL15] = data; break;
case FGA_CTL16 : LOG(("FGA_CTL16 - not implemented\n")); m_fga002[FGA_CTL16] = data; break;
case FGA_FMBCTL : LOG("FGA_FMBCTL - not implemented\n"); m_fga002[FGA_FMBCTL] = data; break;
case FGA_FMBAREA : LOG("FGA_FMBAREA - not implemented\n"); m_fga002[FGA_FMBAREA] = data; break;
case FGA_AUXSRCSTART : LOG("FGA_AUXSRCSTART - not implemented\n"); m_fga002[FGA_AUXSRCSTART] = data; break;
case FGA_AUXDSTSTART : LOG("FGA_AUXDSTSTART - not implemented\n"); m_fga002[FGA_AUXDSTSTART] = data; break;
case FGA_AUXSRCTERM : LOG("FGA_AUXSRCTERM - not implemented\n"); m_fga002[FGA_AUXSRCTERM] = data; break;
case FGA_AUXDSTTERM : LOG("FGA_AUXDSTTERM - not implemented\n"); m_fga002[FGA_AUXDSTTERM] = data; break;
case FGA_CTL13 : LOG("FGA_CTL13 - not implemented\n"); m_fga002[FGA_CTL13] = data; break;
case FGA_CTL14 : LOG("FGA_CTL14 - not implemented\n"); m_fga002[FGA_CTL14] = data; break;
case FGA_CTL15 : LOG("FGA_CTL15 - not implemented\n"); m_fga002[FGA_CTL15] = data; break;
case FGA_CTL16 : LOG("FGA_CTL16 - not implemented\n"); m_fga002[FGA_CTL16] = data; break;
case FGA_ISTIM0 : do_fga002reg_istim0_w(data); break;
case FGA_ISLOCAL0 : do_fga002reg_islocal0_w(data); break;
case FGA_ISLOCAL1 : do_fga002reg_islocal1_w(data); break;
@ -706,72 +709,72 @@ WRITE8_MEMBER (fga002_device::write){
case FGA_ISLOCAL5 : do_fga002reg_islocal5_w(data); break;
case FGA_ISLOCAL6 : do_fga002reg_islocal6_w(data); break;
case FGA_ISLOCAL7 : do_fga002reg_islocal7_w(data); break;
case FGA_ISDMANORM : LOG(("FGA_ISDMANORM - not implemented\n")); m_fga002[FGA_ISDMANORM] = data; break;
case FGA_ISDMAERR : LOG(("FGA_ISDMAERR - not implemented\n")); m_fga002[FGA_ISDMAERR] = data; break;
case FGA_ISFMB0REF : LOG(("FGA_ISFMB0REF - not implemented\n")); m_fga002[FGA_ISFMB0REF] = data; break;
case FGA_ISFMB1REF : LOG(("FGA_ISFMB1REF - not implemented\n")); m_fga002[FGA_ISFMB1REF] = data; break;
case FGA_ISPARITY : LOG(("FGA_ISPARITY - not implemented\n")); m_fga002[FGA_ISPARITY] = data; break;
case FGA_DMARUNCTL : LOG(("FGA_DMARUNCTL - not implemented\n")); m_fga002[FGA_DMARUNCTL] = data; break;
case FGA_ISABORT : LOG(("FGA_ISABORT - not implemented\n")); m_fga002[FGA_ISABORT] = data; break;
case FGA_ISFMB0MES : LOG(("FGA_ISFMB0MES - not implemented\n")); m_fga002[FGA_ISFMB0MES] = data; break;
case FGA_ISFMB1MES : LOG(("FGA_ISFMB1MES - not implemented\n")); m_fga002[FGA_ISFMB1MES] = data; break;
case FGA_ABORTPIN : LOG(("FGA_ABORTPIN - not implemented\n")); m_fga002[FGA_ABORTPIN] = data; break;
case FGA_ISDMANORM : LOG("FGA_ISDMANORM - not implemented\n"); m_fga002[FGA_ISDMANORM] = data; break;
case FGA_ISDMAERR : LOG("FGA_ISDMAERR - not implemented\n"); m_fga002[FGA_ISDMAERR] = data; break;
case FGA_ISFMB0REF : LOG("FGA_ISFMB0REF - not implemented\n"); m_fga002[FGA_ISFMB0REF] = data; break;
case FGA_ISFMB1REF : LOG("FGA_ISFMB1REF - not implemented\n"); m_fga002[FGA_ISFMB1REF] = data; break;
case FGA_ISPARITY : LOG("FGA_ISPARITY - not implemented\n"); m_fga002[FGA_ISPARITY] = data; break;
case FGA_DMARUNCTL : LOG("FGA_DMARUNCTL - not implemented\n"); m_fga002[FGA_DMARUNCTL] = data; break;
case FGA_ISABORT : LOG("FGA_ISABORT - not implemented\n"); m_fga002[FGA_ISABORT] = data; break;
case FGA_ISFMB0MES : LOG("FGA_ISFMB0MES - not implemented\n"); m_fga002[FGA_ISFMB0MES] = data; break;
case FGA_ISFMB1MES : LOG("FGA_ISFMB1MES - not implemented\n"); m_fga002[FGA_ISFMB1MES] = data; break;
case FGA_ABORTPIN : LOG("FGA_ABORTPIN - not implemented\n"); m_fga002[FGA_ABORTPIN] = data; break;
case FGA_TIM0COUNT : do_fga002reg_tim0count_w(data); break;
default:
LOG(("Unsupported register %04x\n", offset));
LOG("Unsupported register %04x\n", offset);
}
}
READ8_MEMBER (fga002_device::read){
uint8_t ret = 0;
LOG(("%s[%04x] ", FUNCNAME, offset));
LOG("%s[%04x] ", FUNCNAME, offset);
switch(offset)
{
case FGA_SPECIALENA : ret = m_fga002[FGA_SPECIALENA]; LOG(("FGA_SPECIALENA returns %02x - not implemented\n", ret)); break;
case FGA_RSVMECALL : ret = m_fga002[FGA_RSVMECALL]; LOG(("FGA_RSVMECALL returns %02x - not implemented\n", ret)); break;
case FGA_RSKEYRES : ret = m_fga002[FGA_RSKEYRES]; LOG(("FGA_RSKEYRES returns %02x - not implemented\n", ret)); break;
case FGA_RSCPUCALL : ret = m_fga002[FGA_RSCPUCALL]; LOG(("FGA_RSCPUCALL returns %02x - not implemented\n", ret)); break;
case FGA_RSLOCSW : ret = m_fga002[FGA_RSLOCSW]; LOG(("FGA_RSLOCSW returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX0 : ret = m_fga002[FGA_ICRMBOX0]; LOG(("FGA_ICRMBOX0 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX1 : ret = m_fga002[FGA_ICRMBOX1]; LOG(("FGA_ICRMBOX1 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX2 : ret = m_fga002[FGA_ICRMBOX2]; LOG(("FGA_ICRMBOX2 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX3 : ret = m_fga002[FGA_ICRMBOX3]; LOG(("FGA_ICRMBOX3 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX4 : ret = m_fga002[FGA_ICRMBOX4]; LOG(("FGA_ICRMBOX4 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX5 : ret = m_fga002[FGA_ICRMBOX5]; LOG(("FGA_ICRMBOX5 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX6 : ret = m_fga002[FGA_ICRMBOX6]; LOG(("FGA_ICRMBOX6 returns %02x - not implemented\n", ret)); break;
case FGA_ICRMBOX7 : ret = m_fga002[FGA_ICRMBOX7]; LOG(("FGA_ICRMBOX7 returns %02x - not implemented\n", ret)); break;
case FGA_VMEPAGE : ret = m_fga002[FGA_VMEPAGE]; LOG(("FGA_VMEPAGE returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME1 : ret = m_fga002[FGA_ICRVME1]; LOG(("FGA_ICRVME1 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME2 : ret = m_fga002[FGA_ICRVME2]; LOG(("FGA_ICRVME2 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME3 : ret = m_fga002[FGA_ICRVME3]; LOG(("FGA_ICRVME3 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME4 : ret = m_fga002[FGA_ICRVME4]; LOG(("FGA_ICRVME4 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME5 : ret = m_fga002[FGA_ICRVME5]; LOG(("FGA_ICRVME5 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME6 : ret = m_fga002[FGA_ICRVME6]; LOG(("FGA_ICRVME6 returns %02x - not implemented\n", ret)); break;
case FGA_ICRVME7 : ret = m_fga002[FGA_ICRVME7]; LOG(("FGA_ICRVME7 returns %02x - not implemented\n", ret)); break;
case FGA_SPECIALENA : ret = m_fga002[FGA_SPECIALENA]; LOG("FGA_SPECIALENA returns %02x - not implemented\n", ret); break;
case FGA_RSVMECALL : ret = m_fga002[FGA_RSVMECALL]; LOG("FGA_RSVMECALL returns %02x - not implemented\n", ret); break;
case FGA_RSKEYRES : ret = m_fga002[FGA_RSKEYRES]; LOG("FGA_RSKEYRES returns %02x - not implemented\n", ret); break;
case FGA_RSCPUCALL : ret = m_fga002[FGA_RSCPUCALL]; LOG("FGA_RSCPUCALL returns %02x - not implemented\n", ret); break;
case FGA_RSLOCSW : ret = m_fga002[FGA_RSLOCSW]; LOG("FGA_RSLOCSW returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX0 : ret = m_fga002[FGA_ICRMBOX0]; LOG("FGA_ICRMBOX0 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX1 : ret = m_fga002[FGA_ICRMBOX1]; LOG("FGA_ICRMBOX1 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX2 : ret = m_fga002[FGA_ICRMBOX2]; LOG("FGA_ICRMBOX2 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX3 : ret = m_fga002[FGA_ICRMBOX3]; LOG("FGA_ICRMBOX3 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX4 : ret = m_fga002[FGA_ICRMBOX4]; LOG("FGA_ICRMBOX4 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX5 : ret = m_fga002[FGA_ICRMBOX5]; LOG("FGA_ICRMBOX5 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX6 : ret = m_fga002[FGA_ICRMBOX6]; LOG("FGA_ICRMBOX6 returns %02x - not implemented\n", ret); break;
case FGA_ICRMBOX7 : ret = m_fga002[FGA_ICRMBOX7]; LOG("FGA_ICRMBOX7 returns %02x - not implemented\n", ret); break;
case FGA_VMEPAGE : ret = m_fga002[FGA_VMEPAGE]; LOG("FGA_VMEPAGE returns %02x - not implemented\n", ret); break;
case FGA_ICRVME1 : ret = m_fga002[FGA_ICRVME1]; LOG("FGA_ICRVME1 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME2 : ret = m_fga002[FGA_ICRVME2]; LOG("FGA_ICRVME2 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME3 : ret = m_fga002[FGA_ICRVME3]; LOG("FGA_ICRVME3 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME4 : ret = m_fga002[FGA_ICRVME4]; LOG("FGA_ICRVME4 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME5 : ret = m_fga002[FGA_ICRVME5]; LOG("FGA_ICRVME5 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME6 : ret = m_fga002[FGA_ICRVME6]; LOG("FGA_ICRVME6 returns %02x - not implemented\n", ret); break;
case FGA_ICRVME7 : ret = m_fga002[FGA_ICRVME7]; LOG("FGA_ICRVME7 returns %02x - not implemented\n", ret); break;
case FGA_ICRTIM0 : ret = do_fga002reg_icrtim0_r(); break;
case FGA_ICRDMANORM : ret = m_fga002[FGA_ICRDMANORM]; LOG(("FGA_ICRDMANORM returns %02x - not implemented\n", ret)); break;
case FGA_ICRDMAERR : ret = m_fga002[FGA_ICRDMAERR]; LOG(("FGA_ICRDMAERR returns %02x - not implemented\n", ret)); break;
case FGA_CTL1 : ret = m_fga002[FGA_CTL1]; LOG(("FGA_CTL1 returns %02x - not implemented\n", ret)); break;
case FGA_CTL2 : ret = m_fga002[FGA_CTL2]; LOG(("FGA_CTL2 returns %02x - not implemented\n", ret)); break;
case FGA_ICRFMB0REF : ret = m_fga002[FGA_ICRFMB0REF]; LOG(("FGA_ICRFMB0REF returns %02x - not implemented\n", ret)); break;
case FGA_ICRFMB1REF : ret = m_fga002[FGA_ICRFMB1REF]; LOG(("FGA_ICRFMB1REF returns %02x - not implemented\n", ret)); break;
case FGA_ICRFMB0MES : ret = m_fga002[FGA_ICRFMB0MES]; LOG(("FGA_ICRFMB0MES returns %02x - not implemented\n", ret)); break;
case FGA_ICRFMB1MES : ret = m_fga002[FGA_ICRFMB1MES]; LOG(("FGA_ICRFMB1MES returns %02x - not implemented\n", ret)); break;
case FGA_ICRDMANORM : ret = m_fga002[FGA_ICRDMANORM]; LOG("FGA_ICRDMANORM returns %02x - not implemented\n", ret); break;
case FGA_ICRDMAERR : ret = m_fga002[FGA_ICRDMAERR]; LOG("FGA_ICRDMAERR returns %02x - not implemented\n", ret); break;
case FGA_CTL1 : ret = m_fga002[FGA_CTL1]; LOG("FGA_CTL1 returns %02x - not implemented\n", ret); break;
case FGA_CTL2 : ret = m_fga002[FGA_CTL2]; LOG("FGA_CTL2 returns %02x - not implemented\n", ret); break;
case FGA_ICRFMB0REF : ret = m_fga002[FGA_ICRFMB0REF]; LOG("FGA_ICRFMB0REF returns %02x - not implemented\n", ret); break;
case FGA_ICRFMB1REF : ret = m_fga002[FGA_ICRFMB1REF]; LOG("FGA_ICRFMB1REF returns %02x - not implemented\n", ret); break;
case FGA_ICRFMB0MES : ret = m_fga002[FGA_ICRFMB0MES]; LOG("FGA_ICRFMB0MES returns %02x - not implemented\n", ret); break;
case FGA_ICRFMB1MES : ret = m_fga002[FGA_ICRFMB1MES]; LOG("FGA_ICRFMB1MES returns %02x - not implemented\n", ret); break;
case FGA_CTL3 : ret = do_fga002reg_ctl3_r(); break;
case FGA_CTL4 : ret = m_fga002[FGA_CTL4]; LOG(("FGA_CTL4 returns %02x - not implemented\n", ret)); break;
case FGA_ICRPARITY : ret = m_fga002[FGA_ICRPARITY]; LOG(("FGA_ICRPARITY returns %02x - not implemented\n", ret)); break;
case FGA_AUXPINCTL : ret = m_fga002[FGA_AUXPINCTL]; LOG(("FGA_AUXPINCTL returns %02x - not implemented\n", ret)); break;
case FGA_CTL5 : ret = m_fga002[FGA_CTL5]; LOG(("FGA_CTL5 returns %02x - not implemented\n", ret)); break;
case FGA_AUXFIFWEX : ret = m_fga002[FGA_AUXFIFWEX]; LOG(("FGA_AUXFIFWEX returns %02x - not implemented\n", ret)); break;
case FGA_AUXFIFREX : ret = m_fga002[FGA_AUXFIFREX]; LOG(("FGA_AUXFIFREX returns %02x - not implemented\n", ret)); break;
case FGA_CTL6 : ret = m_fga002[FGA_CTL6]; LOG(("FGA_CTL6 returns %02x - not implemented\n", ret)); break;
case FGA_CTL7 : ret = m_fga002[FGA_CTL7]; LOG(("FGA_CTL7 returns %02x - not implemented\n", ret)); break;
case FGA_CTL8 : ret = m_fga002[FGA_CTL8]; LOG(("FGA_CTL8 returns %02x - not implemented\n", ret)); break;
case FGA_CTL9 : ret = m_fga002[FGA_CTL9]; LOG(("FGA_CTL9 returns %02x - not implemented\n", ret)); break;
case FGA_ICRABORT : ret = m_fga002[FGA_ICRABORT]; LOG(("FGA_ICRABORT returns %02x - not implemented\n", ret)); break;
case FGA_ICRACFAIL : ret = m_fga002[FGA_ICRACFAIL]; LOG(("FGA_ICRACFAIL returns %02x - not implemented\n", ret)); break;
case FGA_ICRSYSFAIL : ret = m_fga002[FGA_ICRSYSFAIL]; LOG(("FGA_ICRSYSFAIL returns %02x - not implemented\n", ret)); break;
case FGA_CTL4 : ret = m_fga002[FGA_CTL4]; LOG("FGA_CTL4 returns %02x - not implemented\n", ret); break;
case FGA_ICRPARITY : ret = m_fga002[FGA_ICRPARITY]; LOG("FGA_ICRPARITY returns %02x - not implemented\n", ret); break;
case FGA_AUXPINCTL : ret = m_fga002[FGA_AUXPINCTL]; LOG("FGA_AUXPINCTL returns %02x - not implemented\n", ret); break;
case FGA_CTL5 : ret = m_fga002[FGA_CTL5]; LOG("FGA_CTL5 returns %02x - not implemented\n", ret); break;
case FGA_AUXFIFWEX : ret = m_fga002[FGA_AUXFIFWEX]; LOG("FGA_AUXFIFWEX returns %02x - not implemented\n", ret); break;
case FGA_AUXFIFREX : ret = m_fga002[FGA_AUXFIFREX]; LOG("FGA_AUXFIFREX returns %02x - not implemented\n", ret); break;
case FGA_CTL6 : ret = m_fga002[FGA_CTL6]; LOG("FGA_CTL6 returns %02x - not implemented\n", ret); break;
case FGA_CTL7 : ret = m_fga002[FGA_CTL7]; LOG("FGA_CTL7 returns %02x - not implemented\n", ret); break;
case FGA_CTL8 : ret = m_fga002[FGA_CTL8]; LOG("FGA_CTL8 returns %02x - not implemented\n", ret); break;
case FGA_CTL9 : ret = m_fga002[FGA_CTL9]; LOG("FGA_CTL9 returns %02x - not implemented\n", ret); break;
case FGA_ICRABORT : ret = m_fga002[FGA_ICRABORT]; LOG("FGA_ICRABORT returns %02x - not implemented\n", ret); break;
case FGA_ICRACFAIL : ret = m_fga002[FGA_ICRACFAIL]; LOG("FGA_ICRACFAIL returns %02x - not implemented\n", ret); break;
case FGA_ICRSYSFAIL : ret = m_fga002[FGA_ICRSYSFAIL]; LOG("FGA_ICRSYSFAIL returns %02x - not implemented\n", ret); break;
case FGA_ICRLOCAL0 : ret = do_fga002reg_icrlocal0_r(); break;
case FGA_ICRLOCAL1 : ret = do_fga002reg_icrlocal1_r(); break;
case FGA_ICRLOCAL2 : ret = do_fga002reg_icrlocal2_r(); break;
@ -780,34 +783,34 @@ READ8_MEMBER (fga002_device::read){
case FGA_ICRLOCAL5 : ret = do_fga002reg_icrlocal5_r(); break;
case FGA_ICRLOCAL6 : ret = do_fga002reg_icrlocal6_r(); break;
case FGA_ICRLOCAL7 : ret = do_fga002reg_icrlocal7_r(); break;
case FGA_ENAMCODE : ret = m_fga002[FGA_ENAMCODE]; LOG(("FGA_ENAMCODE returns %02x - not implemented\n", ret)); break;
case FGA_CTL10 : ret = m_fga002[FGA_CTL10]; LOG(("FGA_CTL10 returns %02x - not implemented\n", ret)); break;
case FGA_CTL11 : ret = m_fga002[FGA_CTL11]; LOG(("FGA_CTL11 returns %02x - not implemented\n", ret)); break;
case FGA_MAINUM : ret = m_fga002[FGA_MAINUM]; LOG(("FGA_MAINUM returns %02x - not implemented\n", ret)); break;
case FGA_MAINUU : ret = m_fga002[FGA_MAINUU]; LOG(("FGA_MAINUU returns %02x - not implemented\n", ret)); break;
case FGA_BOTTOMPAGEU : ret = m_fga002[FGA_BOTTOMPAGEU]; LOG(("FGA_BOTTOMPAGEU returns %02x - not implemented\n", ret)); break;
case FGA_BOTTOMPAGEL : ret = m_fga002[FGA_BOTTOMPAGEL]; LOG(("FGA_BOTTOMPAGEL returns %02x - not implemented\n", ret)); break;
case FGA_TOPPAGEU : ret = m_fga002[FGA_TOPPAGEU]; LOG(("FGA_TOPPAGEU returns %02x - not implemented\n", ret)); break;
case FGA_TOPPAGEL : ret = m_fga002[FGA_TOPPAGEL]; LOG(("FGA_TOPPAGEL returns %02x - not implemented\n", ret)); break;
case FGA_MYVMEPAGE : ret = m_fga002[FGA_MYVMEPAGE]; LOG(("FGA_MYVMEPAGE returns %02x - not implemented\n", ret)); break;
case FGA_ENAMCODE : ret = m_fga002[FGA_ENAMCODE]; LOG("FGA_ENAMCODE returns %02x - not implemented\n", ret); break;
case FGA_CTL10 : ret = m_fga002[FGA_CTL10]; LOG("FGA_CTL10 returns %02x - not implemented\n", ret); break;
case FGA_CTL11 : ret = m_fga002[FGA_CTL11]; LOG("FGA_CTL11 returns %02x - not implemented\n", ret); break;
case FGA_MAINUM : ret = m_fga002[FGA_MAINUM]; LOG("FGA_MAINUM returns %02x - not implemented\n", ret); break;
case FGA_MAINUU : ret = m_fga002[FGA_MAINUU]; LOG("FGA_MAINUU returns %02x - not implemented\n", ret); break;
case FGA_BOTTOMPAGEU : ret = m_fga002[FGA_BOTTOMPAGEU]; LOG("FGA_BOTTOMPAGEU returns %02x - not implemented\n", ret); break;
case FGA_BOTTOMPAGEL : ret = m_fga002[FGA_BOTTOMPAGEL]; LOG("FGA_BOTTOMPAGEL returns %02x - not implemented\n", ret); break;
case FGA_TOPPAGEU : ret = m_fga002[FGA_TOPPAGEU]; LOG("FGA_TOPPAGEU returns %02x - not implemented\n", ret); break;
case FGA_TOPPAGEL : ret = m_fga002[FGA_TOPPAGEL]; LOG("FGA_TOPPAGEL returns %02x - not implemented\n", ret); break;
case FGA_MYVMEPAGE : ret = m_fga002[FGA_MYVMEPAGE]; LOG("FGA_MYVMEPAGE returns %02x - not implemented\n", ret); break;
case FGA_TIM0PRELOAD : ret = do_fga002reg_tim0preload_r(); break;
case FGA_TIM0CTL : ret = do_fga002reg_tim0ctl_r(); break;
case FGA_DMASRCATT : ret = m_fga002[FGA_DMASRCATT]; LOG(("FGA_DMASRCATT returns %02x - not implemented\n", ret)); break;
case FGA_DMADSTATT : ret = m_fga002[FGA_DMADSTATT]; LOG(("FGA_DMADSTATT returns %02x - not implemented\n", ret)); break;
case FGA_DMA_GENERAL : ret = m_fga002[FGA_DMA_GENERAL]; LOG(("FGA_DMA_GENERAL returns %02x - not implemented\n", ret)); break;
case FGA_CTL12 : ret = m_fga002[FGA_CTL12]; LOG(("FGA_CTL12 returns %02x - not implemented\n", ret)); break;
case FGA_LIOTIMING : ret = m_fga002[FGA_LIOTIMING]; LOG(("FGA_LIOTIMING returns %02x - not implemented\n", ret)); break;
case FGA_DMASRCATT : ret = m_fga002[FGA_DMASRCATT]; LOG("FGA_DMASRCATT returns %02x - not implemented\n", ret); break;
case FGA_DMADSTATT : ret = m_fga002[FGA_DMADSTATT]; LOG("FGA_DMADSTATT returns %02x - not implemented\n", ret); break;
case FGA_DMA_GENERAL : ret = m_fga002[FGA_DMA_GENERAL]; LOG("FGA_DMA_GENERAL returns %02x - not implemented\n", ret); break;
case FGA_CTL12 : ret = m_fga002[FGA_CTL12]; LOG("FGA_CTL12 returns %02x - not implemented\n", ret); break;
case FGA_LIOTIMING : ret = m_fga002[FGA_LIOTIMING]; LOG("FGA_LIOTIMING returns %02x - not implemented\n", ret); break;
case FGA_LOCALIACK : ret = do_fga002reg_localiack_r(); break;
case FGA_FMBCTL : ret = m_fga002[FGA_FMBCTL]; LOG(("FGA_FMBCTL returns %02x - not implemented\n", ret)); break;
case FGA_FMBAREA : ret = m_fga002[FGA_FMBAREA]; LOG(("FGA_FMBAREA returns %02x - not implemented\n", ret)); break;
case FGA_AUXSRCSTART : ret = m_fga002[FGA_AUXSRCSTART]; LOG(("FGA_AUXSRCSTART returns %02x - not implemented\n", ret)); break;
case FGA_AUXDSTSTART : ret = m_fga002[FGA_AUXDSTSTART]; LOG(("FGA_AUXDSTSTART returns %02x - not implemented\n", ret)); break;
case FGA_AUXSRCTERM : ret = m_fga002[FGA_AUXSRCTERM]; LOG(("FGA_AUXSRCTERM returns %02x - not implemented\n", ret)); break;
case FGA_AUXDSTTERM : ret = m_fga002[FGA_AUXDSTTERM]; LOG(("FGA_AUXDSTTERM returns %02x - not implemented\n", ret)); break;
case FGA_CTL13 : ret = m_fga002[FGA_CTL13]; LOG(("FGA_CTL13 returns %02x - not implemented\n", ret)); break;
case FGA_CTL14 : ret = m_fga002[FGA_CTL14]; LOG(("FGA_CTL14 returns %02x - not implemented\n", ret)); break;
case FGA_CTL15 : ret = m_fga002[FGA_CTL15]; LOG(("FGA_CTL15 returns %02x - not implemented\n", ret)); break;
case FGA_CTL16 : ret = m_fga002[FGA_CTL16]; LOG(("FGA_CTL16 returns %02x - not implemented\n", ret)); break;
case FGA_FMBCTL : ret = m_fga002[FGA_FMBCTL]; LOG("FGA_FMBCTL returns %02x - not implemented\n", ret); break;
case FGA_FMBAREA : ret = m_fga002[FGA_FMBAREA]; LOG("FGA_FMBAREA returns %02x - not implemented\n", ret); break;
case FGA_AUXSRCSTART : ret = m_fga002[FGA_AUXSRCSTART]; LOG("FGA_AUXSRCSTART returns %02x - not implemented\n", ret); break;
case FGA_AUXDSTSTART : ret = m_fga002[FGA_AUXDSTSTART]; LOG("FGA_AUXDSTSTART returns %02x - not implemented\n", ret); break;
case FGA_AUXSRCTERM : ret = m_fga002[FGA_AUXSRCTERM]; LOG("FGA_AUXSRCTERM returns %02x - not implemented\n", ret); break;
case FGA_AUXDSTTERM : ret = m_fga002[FGA_AUXDSTTERM]; LOG("FGA_AUXDSTTERM returns %02x - not implemented\n", ret); break;
case FGA_CTL13 : ret = m_fga002[FGA_CTL13]; LOG("FGA_CTL13 returns %02x - not implemented\n", ret); break;
case FGA_CTL14 : ret = m_fga002[FGA_CTL14]; LOG("FGA_CTL14 returns %02x - not implemented\n", ret); break;
case FGA_CTL15 : ret = m_fga002[FGA_CTL15]; LOG("FGA_CTL15 returns %02x - not implemented\n", ret); break;
case FGA_CTL16 : ret = m_fga002[FGA_CTL16]; LOG("FGA_CTL16 returns %02x - not implemented\n", ret); break;
case FGA_ISTIM0 : ret = do_fga002reg_istim0_r(); break;
case FGA_ISLOCAL0 : ret = do_fga002reg_islocal0_r(); break;
case FGA_ISLOCAL1 : ret = do_fga002reg_islocal1_r(); break;
@ -817,19 +820,19 @@ READ8_MEMBER (fga002_device::read){
case FGA_ISLOCAL5 : ret = do_fga002reg_islocal5_r(); break;
case FGA_ISLOCAL6 : ret = do_fga002reg_islocal6_r(); break;
case FGA_ISLOCAL7 : ret = do_fga002reg_islocal7_r(); break;
case FGA_ISDMANORM : ret = m_fga002[FGA_ISDMANORM]; LOG(("FGA_ISDMANORM returns %02x - not implemented\n", ret)); break;
case FGA_ISDMAERR : ret = m_fga002[FGA_ISDMAERR]; LOG(("FGA_ISDMAERR returns %02x - not implemented\n", ret)); break;
case FGA_ISFMB0REF : ret = m_fga002[FGA_ISFMB0REF]; LOG(("FGA_ISFMB0REF returns %02x - not implemented\n", ret)); break;
case FGA_ISFMB1REF : ret = m_fga002[FGA_ISFMB1REF]; LOG(("FGA_ISFMB1REF returns %02x - not implemented\n", ret)); break;
case FGA_ISPARITY : ret = m_fga002[FGA_ISPARITY]; LOG(("FGA_ISPARITY returns %02x - not implemented\n", ret)); break;
case FGA_DMARUNCTL : ret = m_fga002[FGA_DMARUNCTL]; LOG(("FGA_DMARUNCTL returns %02x - not implemented\n", ret)); break;
case FGA_ISABORT : ret = m_fga002[FGA_ISABORT]; LOG(("FGA_ISABORT returns %02x - not implemented\n", ret)); break;
case FGA_ISFMB0MES : ret = m_fga002[FGA_ISFMB0MES]; LOG(("FGA_ISFMB0MES returns %02x - not implemented\n", ret)); break;
case FGA_ISFMB1MES : ret = m_fga002[FGA_ISFMB1MES]; LOG(("FGA_ISFMB1MES returns %02x - not implemented\n", ret)); break;
case FGA_ABORTPIN : ret = m_fga002[FGA_ABORTPIN]; LOG(("FGA_ABORTPIN returns %02x - not implemented\n", ret)); break;
case FGA_ISDMANORM : ret = m_fga002[FGA_ISDMANORM]; LOG("FGA_ISDMANORM returns %02x - not implemented\n", ret); break;
case FGA_ISDMAERR : ret = m_fga002[FGA_ISDMAERR]; LOG("FGA_ISDMAERR returns %02x - not implemented\n", ret); break;
case FGA_ISFMB0REF : ret = m_fga002[FGA_ISFMB0REF]; LOG("FGA_ISFMB0REF returns %02x - not implemented\n", ret); break;
case FGA_ISFMB1REF : ret = m_fga002[FGA_ISFMB1REF]; LOG("FGA_ISFMB1REF returns %02x - not implemented\n", ret); break;
case FGA_ISPARITY : ret = m_fga002[FGA_ISPARITY]; LOG("FGA_ISPARITY returns %02x - not implemented\n", ret); break;
case FGA_DMARUNCTL : ret = m_fga002[FGA_DMARUNCTL]; LOG("FGA_DMARUNCTL returns %02x - not implemented\n", ret); break;
case FGA_ISABORT : ret = m_fga002[FGA_ISABORT]; LOG("FGA_ISABORT returns %02x - not implemented\n", ret); break;
case FGA_ISFMB0MES : ret = m_fga002[FGA_ISFMB0MES]; LOG("FGA_ISFMB0MES returns %02x - not implemented\n", ret); break;
case FGA_ISFMB1MES : ret = m_fga002[FGA_ISFMB1MES]; LOG("FGA_ISFMB1MES returns %02x - not implemented\n", ret); break;
case FGA_ABORTPIN : ret = m_fga002[FGA_ABORTPIN]; LOG("FGA_ABORTPIN returns %02x - not implemented\n", ret); break;
case FGA_TIM0COUNT : ret = do_fga002reg_tim0count_r(); break;
default:
LOG(("Unsupported register %04x\n", offset));
LOG("Unsupported register %04x\n", offset);
}
return ret;
}

34
src/mame/drivers/fccpu30.cpp
View File

@ -209,27 +209,21 @@
#include "machine/clock.h"
//#include "machine/timekpr.h"
#define LOG_GENERAL 0x01
#define LOG_SETUP 0x02
#define LOG_PRINTF 0x04
#define LOG_INIT 0x08
#define LOG_READ 0x10
#define LOG_INT 0x20
//#define LOG_GENERAL (1U << 0)
#define LOG_SETUP (1U << 1)
#define LOG_READ (1U << 2)
#define LOG_INT (1U << 3)
#define LOG_INIT (1U << 4)
#define VERBOSE 0 // (LOG_PRINTF | LOG_SETUP | LOG_GENERAL)
//#define VERBOSE (LOG_GENERAL | LOG_SETUP)
//#define LOG_OUTPUT_FUNC printf
#define LOGMASK(mask, ...) do { if (VERBOSE & mask) logerror(__VA_ARGS__); } while (0)
#define LOGLEVEL(mask, level, ...) do { if ((VERBOSE & mask) >= level) logerror(__VA_ARGS__); } while (0)
#include "logmacro.h"
#define LOG(...) LOGMASK(LOG_GENERAL, __VA_ARGS__)
#define LOGSETUP(...) LOGMASK(LOG_SETUP, __VA_ARGS__)
#define LOGINIT(...) LOGMASK(LOG_INIT, __VA_ARGS__)
#define LOGR(...) LOGMASK(LOG_READ, __VA_ARGS__)
#define LOGINT(...) LOGMASK(LOG_INT, __VA_ARGS__)
#if VERBOSE & LOG_PRINTF
#define logerror printf
#endif
#define LOGSETUP(...) LOGMASKED(LOG_SETUP, __VA_ARGS__)
#define LOGR(...) LOGMASKED(LOG_READ, __VA_ARGS__)
#define LOGINT(...) LOGMASKED(LOG_INT, __VA_ARGS__)
#define LOGINIT(...) LOGMASKED(LOG_INIT, __VA_ARGS__)
#ifdef _MSC_VER
#define FUNCNAME __func__
@ -704,7 +698,7 @@ static MACHINE_CONFIG_START (cpu30, cpu30_state)
/* DUSCC2 interrupt signal REQN is connected to LOCAL IRQ5 of the FGA-002 and level is programmable */
MCFG_DUSCC_OUT_INT_CB(DEVWRITELINE("fga002", fga002_device, lirq5_w))
MCFG_RS232_PORT_ADD (RS232P1_TAG, default_rs232_devices, nullptr)
MCFG_RS232_PORT_ADD (RS232P1_TAG, default_rs232_devices, "terminal")
MCFG_RS232_RXD_HANDLER (DEVWRITELINE ("duscc", duscc68562_device, rxb_w))
MCFG_RS232_CTS_HANDLER (DEVWRITELINE ("duscc", duscc68562_device, ctsb_w))
@ -716,7 +710,7 @@ static MACHINE_CONFIG_START (cpu30, cpu30_state)
MCFG_RS232_RXD_HANDLER (DEVWRITELINE ("duscc2", duscc68562_device, rxb_w))
MCFG_RS232_CTS_HANDLER (DEVWRITELINE ("duscc2", duscc68562_device, ctsb_w))
MCFG_RS232_PORT_ADD (RS232P4_TAG, default_rs232_devices, nullptr)
MCFG_RS232_PORT_ADD (RS232P4_TAG, default_rs232_devices, "terminal")
MCFG_RS232_RXD_HANDLER (DEVWRITELINE ("duscc", duscc68562_device, rxa_w))
MCFG_RS232_CTS_HANDLER (DEVWRITELINE ("duscc", duscc68562_device, ctsa_w))