A firewall is a(1)system designed to(2)an organization's network against threats.A.operatingB.programmingC.securityD.service
A firewall is a(1)system designed to(2)an organization's network against threats.
A.operating
B.programming
C.security
D.service
相关考题:
classSock2{Stringcolor;publicbooleanequals(Objecto){returncolor.equals(((Sock2)o).color);}}classTestSocks{publicstaticvoidmain(String[]args){Sock2s1=newSock2();s1.color=blue;Sock2s2=newSock2();s2.color=blue;if(s1.equals(s2))System.out.print(equals);if(s1==s2)System.out.print(==);}}结果为:()A.==B.equalsC.equals==D.无结果输出
publicclassSyncTest{publicstaticvoidmain(Stringargs){finalStringBuffers1=newStringBuffer();finalStringBuffers2=newStringBuffer();newThread(){publicvoidrun(){synchronized(s1){s2.append(A”);synchronized(s2){s2.append(B”);System.out.print(s1);System.out.print(s2);}}}}.start();newThread(){publicvoidrun(){synchronized(s2){s2.append(C”);synchronized(s1){s1.append(D”);System.out.print(s2);System.out.print(s1);}}}}.start();}}Whichtwostatementsaretrue?()
下列代码的执行结果是()。publicclasstest5{publicstaticvoidmain(Stringargs[]){Strings1=newString("hello");Strings2=newString("hello");System.out.prim(s1==s2);System.out.print(",");System.out.println(s1.equals(s2));}A.true,falseB.true,trueC.false,trueD.false,false
下列代码的执行结果是( )。 public class Test{ public static void main String args[]){ String s1=new String("welcome"); String s2=new String("welcome"); System.out.println(s1==s2); System.out.println(s1.equals(s2)); } }A.false,falseB.false,trueC.true,trueD.true,false
下列代码段的执行结果是( )。 public class Test { public static void main(String args[ ]) { String s1= new String("hello"); String s2= new String("hello"); System.out.println(s1==s2); System.out.println(s1.equal(s2)); } }A.true falseB.true trueC.false trueD.false false
下列代码的执行结果是______。 public class ex55 { public static void main(String args[] ) { String s1=new String("hello"); String s2=new String("hello"); System.out.print (s1==s2); System.out.print (","); System.out.println (s1.equals (s2)); } }A.true, falseB.true, trueC.false, trueD.false, false
下列代码段的执行结果是( )。 public class Test { public static void main(String args[]) } String s1=new String("hello"); String s2=new String{"hello"); System.out.println(s1==s2); System.out.println(s1.equal(s2)); } }A.true falseB.true trueC.false trueD.false false
某全国连锁企业的总部和分布在全国各地的30家分公司之间经常需要传输各种内部数据,因此公司决定在总部和各分公司之间建立VPN技术。具体拓扑如下:配置部分只显示了与总部与分公司1的配置。根据拓扑完成问题1-问题3。[问题1](3分):在总部与分公司之间相连的VPN方式是(1),在IPsec工作模式中有传输模式和隧道模式,其中将源IP数据包整体封装后再进行传输的模式是(2).1备选答案:A.站点到站点 B.端到端C.端到站点[问题2](13分):请将相关配置补充完整。总部防火墙firewall1的部分配置如下。 (3)[FIREWALL1] interface(4)[FIREWALL1-GigabitEthernet1/0/2] ip address (5)[FIREWALL1-GigabitEthernet1/0/2] quit[FIREWALL1] interface GigabitEthernet 1/0/1[FIREWALL1-GigabitEthernet1/0/1] ip address 202.1.3.1 24[FIREWALL1-GigabitEthernet1/0/1] quit# 配置接口加入相应的安全区域。[FIREWALL1] firewall zone trust [FIREWALL1-zone-trust] add interface (6)[FIREWALL1-zone-trust] quit[FIREWALL1](7)[FIREWALL1-zone-untrust] add interface GigabitEthernet 1/0/1[FIREWALL1-zone-untrust] quit2. 配置安全策略,允许私网指定网段进行报文交互。# 配置Trust域与Untrust域的安全策略,允许封装前和解封后的报文能通过[FIREWALL1](8)[FIREWALL1-policy-security] rule name 1[FIREWALL1-policy-security-rule-1] source-zone (9)[FIREWALL1-policy-security-rule-1] destination-zone untrust[FIREWALL1-policy-security-rule-1] source-address (10)[FIREWALL1-policy-security-rule-1] destination-address 192.168.200.0 24[FIREWALL1-policy-security-rule-1] action (11)[FIREWALL1-policy-security-rule-1] quit…..# 配置Local域与Untrust域的安全策略,允许IKE协商报文能正常通过FIREWALL1。[FIREWALL1-policy-security] rule name 3[FIREWALL1-policy-security-rule-3] source-zone local[FIREWALL1-policy-security-rule-3] destination-zone untrust[FIREWALL1-policy-security-rule-3] source-address 202.1.3.1 32[FIREWALL1-policy-security-rule-3] destination-address 202.1.5.1 32[FIREWALL1-policy-security-rule-3] action permit[FIREWALL1-policy-security-rule-3] quit…3. 配置IPSec隧道。# 配置访问控制列表,定义需要保护的数据流。[FIREWALL1] (12)[FIREWALL1-acl-adv-3000] rule permit (13)[FIREWALL1-acl-adv-3000] quit# 配置名称为tran1的IPSec安全提议。[FIREWALL1] ipsec proposal tran1[FIREWALL1-ipsec-proposal-tran1] encapsulation-mode (14)[FIREWALL1-ipsec-proposal-tran1] transform esp[FIREWALL1-ipsec-proposal-tran1] esp authentication-algorithm sha2-256[FIREWALL1-ipsec-proposal-tran1] esp encryption-algorithm aes[FIREWALL1-ipsec-proposal-tran1] quit# 配置序号为10的IKE安全提议。[FIREWALL1] (15)[FIREWALL1-ike-proposal-10] authentication-method pre-share[FIREWALL1-ike-proposal-10] authentication-algorithm sha2-256[FIREWALL1-ike-proposal-10] quit# 配置IKE用户信息表。[FIREWALL1] ike user-table 1[FIREWALL1-ike-user-table-1] user id-type ip 202.1.5.1 pre-shared-key Admin@gkys[FIREWALL1-ike-user-table-1] quit# 配置IKE Peer。[FIREWALL1] ike peer b[FIREWALL1-ike-peer-b] ike-proposal 10[FIREWALL1-ike-peer-b] user-table 1[FIREWALL1-ike-peer-b] quit# 配置名称为map_temp序号为1的IPSec安全策略模板。[FIREWALL1] ipsec policy-template map_temp 1[FIREWALL1-ipsec-policy-template-map_temp-1] security acl 3000[FIREWALL1-ipsec-policy-template-map_temp-1] proposal tran1[FIREWALL1-ipsec-policy-template-map_temp-1] ike-peer b[FIREWALL1-ipsec-policy-template-map_temp-1] reverse-route enable[FIREWALL1-ipsec-policy-template-map_temp-1] quit# 在IPSec安全策略map1中引用安全策略模板map_temp。[FIREWALL1] ipsec policy map1 10 isakmp template map_temp# 在接口GigabitEthernet 1/0/1上应用安全策略map1。[FIREWALL1] interface GigabitEthernet 1/0/1[FIREWALL1-GigabitEthernet1/0/1] ipsec policy map1[FIREWALL1-GigabitEthernet1/0/1] quit [问题3]IPsec中,通过一些协议的处理,可以有效的保护分组安全传输。其中能够确保数据完整性,但是不能确保数据机密性的是(17),而技能报数数据传输的机密性又能保证数据完整性的是(18)
9、请阅读下面的代码 String s1=new String(“abc”); String s2=s1.intern(); String s3=”abc”; System.out.println(s1==s2); System.out.println(s2==s3); System.out.println(s1==s3); 下列选项中,程序的输出结果为()A.false true falseB.false false falseC.false true trueD.false false true
执行完1题的三行代码后,接着执行下面的三行代码: System.out.println(s == s1); System.out.println(s == s2); System.out.println(s1 == s2); 输出的结果是:()A.true true trueB.false false trueC.false fasle falseD.true true false