/* * Copyright (c) 2020-2021 Huawei Device Co., Ltd. * * HDF is dual licensed: you can use it either under the terms of * the GPL, or the BSD license, at your option. * See the LICENSE file in the root of this repository for complete details. */ #include #include "osal_mem.h" #include "hdf_log.h" #include "input_config.h" #define CHECK_PARSER_RET(ret, str) do { \ if ((ret) != HDF_SUCCESS) { \ HDF_LOGE("%s: %s failed, ret = %d", __func__, str, ret); \ return HDF_FAILURE; \ } \ } while (0) #define DEFAULT_I2C_SPEED 400 #define DEFAULT_SPI_SPEED 10000 #define I2C 0 #define SPI 1 int32_t ParseKeyConfig(const struct DeviceResourceNode *node, KeyChipCfg *config) { if (node == NULL || config == NULL) { HDF_LOGE("%s: param is null", __func__); return HDF_FAILURE; } struct DeviceResourceIface *parser = NULL; parser = DeviceResourceGetIfaceInstance(HDF_CONFIG_SOURCE); if (parser == NULL) { HDF_LOGE("%s: instance parser failed", __func__); return HDF_FAILURE; } const struct DeviceResourceNode *keyNode = node; int32_t ret = parser->GetString(keyNode, "keyName", &config->keyName, NULL); CHECK_PARSER_RET(ret, "GetString"); ret = parser->GetUint8(keyNode, "inputType", &config->devType, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint16(keyNode, "gpioNum", &config->gpioNum, 0); CHECK_PARSER_RET(ret, "GetUint32"); ret = parser->GetUint16(keyNode, "irqFlag", &config->irqFlag, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint32(keyNode, "debounceTime", &config->debounceTime, 0); CHECK_PARSER_RET(ret, "GetUint32"); return HDF_SUCCESS; } static int32_t ParseAttr(struct DeviceResourceIface *parser, const struct DeviceResourceNode *attrNode, BoardAttrCfg *attr) { int32_t ret; ret = parser->GetUint8(attrNode, "inputType", &attr->devType, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetString(attrNode, "devName", &attr->devName, NULL); CHECK_PARSER_RET(ret, "GetString"); ret = parser->GetUint32(attrNode, "solutionX", &attr->resolutionX, 0); CHECK_PARSER_RET(ret, "GetUint32"); ret = parser->GetUint32(attrNode, "solutionY", &attr->resolutionY, 0); CHECK_PARSER_RET(ret, "GetUint32"); return HDF_SUCCESS; } static int32_t ParseBus(struct DeviceResourceIface *parser, const struct DeviceResourceNode *busNode, BoardBusCfg *bus) { int32_t ret; ret = parser->GetUint8(busNode, "busType", &bus->busType, 0); CHECK_PARSER_RET(ret, "GetUint8"); if (bus->busType == I2C) { ret = parser->GetUint8(busNode, "busNum", &bus->i2c.busNum, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint16(busNode, "clkGpio", &bus->i2c.clkGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(busNode, "dataGpio", &bus->i2c.dataGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint32Array(busNode, "i2cClkIomux", bus->i2c.i2cClkReg, REG_CONFIG_LEN, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); ret = parser->GetUint32Array(busNode, "i2cDataIomux", bus->i2c.i2cDataReg, REG_CONFIG_LEN, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); } else if (bus->busType == SPI) { ret = parser->GetUint8(busNode, "busNum", &bus->spi.busNum, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint16(busNode, "clkGpio", &bus->spi.clkGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(busNode, "csGpio", &bus->spi.csGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(busNode, "misoGpio", &bus->spi.misoGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(busNode, "mosiGpio", &bus->spi.mosiGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); } else { HDF_LOGE("%s: unknown bus type", __func__); } return HDF_SUCCESS; } static int32_t ParsePins(struct DeviceResourceIface *parser, const struct DeviceResourceNode *pinsNode, BoardPinCfg *pins) { int32_t ret; ret = parser->GetUint16(pinsNode, "rstGpio", &pins->rstGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(pinsNode, "intGpio", &pins->intGpio, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint32Array(pinsNode, "rstRegCfg", pins->rstPinReg, REG_CONFIG_LEN, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); ret = parser->GetUint32Array(pinsNode, "intRegCfg", pins->intPinReg, REG_CONFIG_LEN, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); return HDF_SUCCESS; } static int32_t ParsePower(struct DeviceResourceIface *parser, const struct DeviceResourceNode *powerNode, BoardPwrCfg *power) { int32_t ret; ret = parser->GetUint16(powerNode, "vccType", &power->vcc.pwrType, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(powerNode, "vccNum", &power->vcc.pwrNum, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint32(powerNode, "vccValue", &power->vcc.pwrValue, 0); CHECK_PARSER_RET(ret, "GetUint32"); ret = parser->GetUint16(powerNode, "vciType", &power->vci.pwrType, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint16(powerNode, "vciNum", &power->vci.pwrNum, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint32(powerNode, "vciValue", &power->vci.pwrValue, 0); CHECK_PARSER_RET(ret, "GetUint32"); return HDF_SUCCESS; } static int32_t ParseFeature(struct DeviceResourceIface *parser, const struct DeviceResourceNode *featureNode, BoardFeatureCfg *feature) { int32_t ret; ret = parser->GetUint8(featureNode, "capacitanceTest", &feature->capacitanceTest, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(featureNode, "gestureMode", &feature->gestureMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(featureNode, "gloverMOde", &feature->gloverMOde, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(featureNode, "coverMode", &feature->coverMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(featureNode, "chargerMode", &feature->chargeMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(featureNode, "knuckleMode", &feature->knuckleMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); return HDF_SUCCESS; } int32_t ParseTouchBoardConfig(const struct DeviceResourceNode *node, TouchBoardCfg *config) { int32_t ret; struct DeviceResourceIface *parser = NULL; if (node == NULL || config == NULL) { HDF_LOGE("%s: input param is null", __func__); return HDF_FAILURE; } parser = DeviceResourceGetIfaceInstance(HDF_CONFIG_SOURCE); if (parser == NULL) { HDF_LOGE("%s: invalid parser", __func__); return HDF_FAILURE; } config->boardNode = node; const struct DeviceResourceNode *attrNode = parser->GetChildNode(node, "inputAttr"); const struct DeviceResourceNode *busNode = parser->GetChildNode(node, "busConfig"); const struct DeviceResourceNode *pinsNode = parser->GetChildNode(node, "pinConfig"); const struct DeviceResourceNode *powerNode = parser->GetChildNode(node, "powerConfig"); const struct DeviceResourceNode *featureNode = parser->GetChildNode(node, "featureConfig"); if (attrNode == NULL || busNode == NULL || pinsNode == NULL || powerNode == NULL || featureNode == NULL) { HDF_LOGE("%s: get child node fail!", __func__); return HDF_FAILURE; } ret = ParseAttr(parser, attrNode, &config->attr); CHECK_PARSER_RET(ret, "ParseAttr"); ret = ParseBus(parser, busNode, &config->bus); CHECK_PARSER_RET(ret, "ParseBus"); ret = ParsePins(parser, pinsNode, &config->pins); CHECK_PARSER_RET(ret, "ParsePins"); ret = ParsePower(parser, powerNode, &config->power); CHECK_PARSER_RET(ret, "ParsePower"); ret = ParseFeature(parser, featureNode, &config->feature); CHECK_PARSER_RET(ret, "ParseFeature"); return HDF_SUCCESS; } static int32_t ParsePowerSequence(struct DeviceResourceIface *parser, const struct DeviceResourceNode *seqNode, ChipPwrSeq *pwrSeq) { int32_t ret; uint32_t num = (uint32_t)parser->GetElemNum(seqNode, "powerOnSeq"); pwrSeq->pwrOn.count = num; pwrSeq->pwrOn.buf = (uint32_t *)OsalMemAlloc(sizeof(uint32_t) * num); if (pwrSeq->pwrOn.buf == NULL) { return HDF_FAILURE; } (void)memset_s(pwrSeq->pwrOn.buf, sizeof(uint32_t) * num, 0, sizeof(uint32_t) * num); ret = parser->GetUint32Array(seqNode, "powerOnSeq", pwrSeq->pwrOn.buf, num, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); pwrSeq->suspend.count = parser->GetElemNum(seqNode, "suspendSeq"); num = pwrSeq->suspend.count; pwrSeq->suspend.buf = (uint32_t *)OsalMemAlloc(sizeof(uint32_t) * num); if (pwrSeq->suspend.buf == NULL) { OsalMemFree(pwrSeq->pwrOn.buf); pwrSeq->pwrOn.buf = NULL; return HDF_FAILURE; } (void)memset_s(pwrSeq->suspend.buf, sizeof(uint32_t) * num, 0, sizeof(uint32_t) * num); ret = parser->GetUint32Array(seqNode, "suspendSeq", pwrSeq->suspend.buf, num, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); pwrSeq->resume.count = parser->GetElemNum(seqNode, "resumeSeq"); num = pwrSeq->resume.count; pwrSeq->resume.buf = (uint32_t *)OsalMemAlloc(sizeof(uint32_t) * num); if (pwrSeq->resume.buf == NULL) { OsalMemFree(pwrSeq->pwrOn.buf); pwrSeq->pwrOn.buf = NULL; OsalMemFree(pwrSeq->suspend.buf); pwrSeq->suspend.buf = NULL; return HDF_FAILURE; } (void)memset_s(pwrSeq->resume.buf, sizeof(uint32_t) * num, 0, sizeof(uint32_t) * num); ret = parser->GetUint32Array(seqNode, "resumeSeq", pwrSeq->resume.buf, num, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); pwrSeq->pwrOff.count = parser->GetElemNum(seqNode, "powerOffSeq"); num = pwrSeq->pwrOff.count; pwrSeq->pwrOff.buf = (uint32_t *)OsalMemAlloc(sizeof(uint32_t) * num); if (pwrSeq->pwrOff.buf == NULL) { OsalMemFree(pwrSeq->pwrOn.buf); pwrSeq->pwrOn.buf = NULL; OsalMemFree(pwrSeq->suspend.buf); pwrSeq->suspend.buf = NULL; OsalMemFree(pwrSeq->resume.buf); pwrSeq->resume.buf = NULL; return HDF_FAILURE; } (void)memset_s(pwrSeq->pwrOff.buf, sizeof(uint32_t) * num, 0, sizeof(uint32_t) * num); ret = parser->GetUint32Array(seqNode, "powerOffSeq", pwrSeq->pwrOff.buf, num, 0); CHECK_PARSER_RET(ret, "GetUint32Array"); return HDF_SUCCESS; } int32_t ParseTouchChipConfig(const struct DeviceResourceNode *node, TouchChipCfg *config) { int32_t ret; struct DeviceResourceIface *parser = NULL; if (node == NULL || config == NULL) { HDF_LOGE("%s: point is null", __func__); return HDF_FAILURE; } parser = DeviceResourceGetIfaceInstance(HDF_CONFIG_SOURCE); if (parser == NULL) { HDF_LOGE("%s: instance parser failed", __func__); return HDF_FAILURE; } config->chipNode = node; ret = parser->GetString(node, "chipName", &config->chipName, NULL); CHECK_PARSER_RET(ret, "GetString"); ret = parser->GetString(node, "vendorName", &config->vendorName, NULL); CHECK_PARSER_RET(ret, "GetString"); ret = parser->GetString(node, "chipInfo", &config->chipInfo, NULL); CHECK_PARSER_RET(ret, "GetString"); ret = parser->GetUint16(node, "chipVersion", &config->chipVersion, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint8(node, "busType", &config->bus.busType, 0); CHECK_PARSER_RET(ret, "GetUint8"); if (config->bus.busType == I2C) { ret = parser->GetUint16(node, "irqFlag", &config->bus.chipI2c.irqFlag, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint32(node, "deviceAddr", &config->bus.chipI2c.commAddr, 0); CHECK_PARSER_RET(ret, "GetUint32"); ret = parser->GetUint32(node, "maxSpeed", &config->bus.chipI2c.maxSpeed, DEFAULT_I2C_SPEED); CHECK_PARSER_RET(ret, "GetUint32"); } else { ret = parser->GetUint16(node, "irqFlag", &config->bus.chipSpi.irqFlag, 0); CHECK_PARSER_RET(ret, "GetUint16"); ret = parser->GetUint8(node, "wordMode", &config->bus.chipSpi.wordMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint8(node, "commMode", &config->bus.chipSpi.commMode, 0); CHECK_PARSER_RET(ret, "GetUint8"); ret = parser->GetUint32(node, "maxSpeed", &config->bus.chipSpi.maxSpeed, DEFAULT_SPI_SPEED); CHECK_PARSER_RET(ret, "GetUint32"); } const struct DeviceResourceNode *pwrSeqNode = parser->GetChildNode(node, "powerSequence"); if (pwrSeqNode == NULL) { HDF_LOGE("%s: get powerSequence child node failed", __func__); return HDF_FAILURE; } if (ParsePowerSequence(parser, pwrSeqNode, &config->pwrSeq) != HDF_SUCCESS) { return HDF_FAILURE; } return HDF_SUCCESS; }