FreeCalypso > hg > fc-tourmaline
view src/cs/drivers/drv_app/sim/sim32.c @ 78:c632896652ba
mfw/ti1_key.c: properly initialize notified_keys array
The code in this ti1_key.c layer needs to call kpd_subscribe() and
kpd_define_key_notification() functions in order to register with the
KPD driver. The original code passed KPD_NB_PHYSICAL_KEYS in
nb_notified_keys - this constant is defined to 24 in kpd_cfg.h on all
platforms of interest to us - but it only filled the first 23 slots
in the notified_keys array, resulting in stack garbage being passed
to KPD API functions. The fix consists of initializing the last
missed array slot to KPD_KEY_RECORD, the key ID for the right side
button on the D-Sample handset.
On our current hw targets this "Record" button exists as the EXTRA
button on our Luna keypad board and as the camera button on the
Pirelli DP-L10. There is no support whatsoever for this button
in current BMI+MFW, we have no plans of doing anything with Pirelli's
camera button even if we do get our UI fw running on that phone,
and the Mother's dream of building our own FreeCalypso handset with
the same button arrangement as D-Sample (including the right side
button) is currently very nebulous - but let us nonetheless handle
the full set of buttons on the KPD to MFW interface, and let upper
layers weed out unsupported buttons.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sun, 25 Oct 2020 23:41:01 +0000 |
| parents | 4e78acac3d88 |
| children | b37e6c916df1 |
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/* * SIM32.C * * Pole Star SIM * * Target : ARM * * Copyright (c) Texas Instruments 1995 * */ #define SIM32_C 1 #include "chipset.cfg" #include "main/sys_types.h" #include <assert.h> #include "inth/iq.h" #include "sim.h" #ifdef SIM_DEBUG_TRACE /* working buffer for NULL BYTE */ extern SYS_UWORD8 SIM_dbg_null[]; /* Nucleus variable given the current number of TDMA frames */ extern SYS_UWORD32 IQ_FrameCount; /* working variable to calculate the TDMA ecart */ extern SYS_UWORD16 SIM_dbg_tdma_diff; /* working variable storing the current number of TDMA frames elapsed */ SYS_UWORD32 SIM_dbg_local_count; #endif /* * SIM_IntHandler * * Read cause of SIM interrupt : * * if receive buffer full, read char * if transmitter empty, change direction, transmit a dummy char * */ void SIM_IntHandler(void) { volatile unsigned short it, i, stat, conf1; volatile SYS_UWORD8 ins; volatile SYS_UWORD8 rx; volatile SYS_UWORD8 nack; volatile SYS_UWORD8 nack1; SIM_PORT *p; p = &(Sim[0]); p->rxParityErr = 0; it = p->c->it; if ((it & SIM_IT_ITRX) && !(p->c->maskit & SIM_MASK_RX)) // int on reception { stat = p->c->rx; conf1 = p->conf1; #ifdef SIM_DEBUG_TRACE if ((IQ_FrameCount - SIM_dbg_local_count) > SIM_dbg_tdma_diff) { SIM_dbg_tdma_diff = IQ_FrameCount - SIM_dbg_local_count; } SIM_dbg_local_count = IQ_FrameCount; #endif // Check if reception parity is enable if (((conf1 & SIM_CONF1_CHKPAR) && ((stat & SIM_DRX_STATRXPAR) != 0))\ || ((conf1 & SIM_CONF1_CHKPAR) == 0)) { rx = (SYS_UWORD8) (stat & 0x00FF); ins = p->xbuf[1] & p->hw_mask; nack = (~p->xbuf[1]) & p->hw_mask; switch (p->moderx) { case 0: //mode of normal reception without proc char (like PTS proc) p->rbuf[p->rx_index++] = rx; break; case 1: //mode wait for ACK if ((rx & p->hw_mask) == ins) { p->moderx = 2; } else if ((rx & p->hw_mask) == nack) { p->moderx = 4; } else if (((rx & 0xF0) == 0x60) || ((rx & 0xF0) == 0x90)) { if (rx != 0x60) //in case of error code (SW1/SW2) returned by sim card { p->rSW12[p->SWcount++] = rx; p->moderx = 5; } else { p->null_received = 1; #ifdef SIM_DEBUG_TRACE SIM_dbg_null[0]++; #endif } } else { p->errorSIM = SIM_ERR_ABNORMAL_CASE2; } //if rx = 0x60 wait for ACK break; case 2: //mode reception by block p->rbuf[p->rx_index++] = rx; if(p->expected_data == 256) { if (p->rx_index == 0) { p->moderx = 5; } } else { if (p->rx_index == p->expected_data) { p->moderx = 5; } } break; case 3: //mode reception char by char. reception of proc char if ((rx & p->hw_mask) == ins) { p->moderx = 2; } else if ((rx & p->hw_mask) == nack) { p->moderx = 4; } //if rx = 0x60 wait for ACK else if (rx == 0x60) { p->null_received == 1; #ifdef SIM_DEBUG_TRACE SIM_dbg_null[1]++; #endif } break; case 4: //mode reception char by char. reception of data p->rbuf[p->rx_index++] = rx; p->moderx = 3; //switch to receive proc char mode if(p->expected_data == 256) { if (p->rx_index == 0) { p->moderx = 5; } } else { if (p->rx_index == p->expected_data) { p->moderx = 5; } } break; case 5: //mode wait for procedure character except NULL if ((rx != 0x60) || (p->SWcount != 0)) //treat NULL character only if arriving before SW1 SW2 { p->rSW12[p->SWcount++] = rx; } else { p->null_received = 1; #ifdef SIM_DEBUG_TRACE SIM_dbg_null[2]++; #endif } break; case 6: //give the acknowledge char if (((rx & 0xF0) == 0x60) || ((rx & 0xF0) == 0x90)) { if (rx != 0x60) //in case of error code (SW1/SW2) returned by sim card { p->rSW12[p->SWcount++] = rx; p->moderx = 5; } else { p->null_received = 1; #ifdef SIM_DEBUG_TRACE SIM_dbg_null[3]++; #endif } } else { p->ack = rx; } } } else { p->rxParityErr = 1; } } if ((it & SIM_IT_ITTX) && !(p->c->maskit & SIM_MASK_TX)) { #ifdef SIM_DEBUG_TRACE SIM_dbg_local_count = IQ_FrameCount; #endif // check the transmit parity stat = p->c->stat; if ((stat & SIM_STAT_TXPAR) || ((p->conf1 & SIM_CONF1_CHKPAR) == 0)) //parity disable { if (p->xOut != (p->xIn - 1)) //if only one char transmitted (already transmitted) { //just need to have confirmation of reception if (p->xOut == (p->xIn - 2)) { p->xOut++; p->c->tx = *(p->xOut); // transmit p->conf1 &= ~SIM_CONF1_TXRX; // return the direction p->c->conf1 = p->conf1; } if (p->xOut < (p->xIn - 2)) { p->xOut++; p->c->tx = *(p->xOut); // transmit } } } else { p->c->tx = *(p->xOut); // transmit same char p->txParityErr++; // count number of transmit parity errors } } // Handle errors if ((it & SIM_IT_ITOV) && !(p->c->maskit & SIM_MASK_OV)) { p->errorSIM = SIM_ERR_OVF; } if ((it & SIM_IT_WT) && !(p->c->maskit & SIM_MASK_WT)) { p->errorSIM = SIM_ERR_READ; } // Reset the card in case of NATR to let the program continue if ((it & SIM_IT_NATR) && !(p->c->maskit & SIM_MASK_NATR)) { p->c->cmd = SIM_CMD_STOP; p->errorSIM = SIM_ERR_NATR; } #if ((CHIPSET == 2) || (CHIPSET == 3)) // SIM card insertion / extraction if ((it & SIM_IT_CD) && !(p->c->maskit & SIM_MASK_CD)) { stat = p->c->stat; if ((stat & SIM_STAT_CD) != SIM_STAT_CD) { (p->RemoveFunc)(); p->errorSIM = SIM_ERR_NOCARD; } } #endif } #if ((CHIPSET == 4) || (CHIPSET == 5) || (CHIPSET == 6) || (CHIPSET == 7) || (CHIPSET == 8) || (CHIPSET == 9) || (CHIPSET == 10) || (CHIPSET == 11) || (CHIPSET == 12)) /* * SIM_CD_IntHandler * * Read cause of SIM interrupt : * */ void SIM_CD_IntHandler(void) { volatile unsigned short it_cd, stat; SIM_PORT *p; p = &(Sim[0]); p->rxParityErr = 0; it_cd = p->c->it_cd; // SIM card insertion / extraction if ((it_cd & SIM_IT_CD) && !(p->c->maskit & SIM_MASK_CD)) { stat = p->c->stat; if ((stat & SIM_STAT_CD) != SIM_STAT_CD) { (p->RemoveFunc)(); p->errorSIM = SIM_ERR_NOCARD; } } } #endif // to force this module to be linked SYS_UWORD16 SIM_Dummy(void) { }